Molecular detection ofLeishmaniaspp. in road-killed wild mammals in the Central Western area of the State of São Paulo, Brazil

Richini-Pereira, Virginia Bodelão; Marson, Pamela Merlo; Hayasaka, Enio Yoshinori; Victoria, Cassiano; Silva, Rodrigo Costa da; Langoni, Hélio

doi:10.1186/1678-9199-20-27

Abstract

Background

Road-killed wild animals have been classified as sentinels for detecting such zoonotic pathogens asLeishmaniaspp., offering new opportunities for epidemiological studies of this infection.

Methods

This study aimed to evaluate the presence ofLeishmaniaspp. andLeishmania chagasiDNA by PCR in tissue samples (lung, liver, spleen, kidney, heart, mesenteric lymph node and adrenal gland) from 70 road-killed wild animals.

Results

DNA was detected in tissues of oneCavia aperea(Brazilian guinea pig), fiveCerdocyon thous(crab-eating fox), oneDasypus septemcinctus(seven-banded armadillo), twoDidelphis albiventris(white-eared opossum), oneHydrochoerus hydrochoeris(capybara), twoMyrmecophaga tridactyla(giant anteater), oneProcyon cancrivorus(crab-eating raccoon), twoSphiggurus spinosus(porcupine) and oneTamandua tetradactyla(lesser anteater) from different locations in the Central Western part of São Paulo state. TheLeishmania chagasiDNA were confirmed in mesenteric lymph node of oneCerdocyon thous. Results indicated common infection in wild animals.

Conclusions

The approach employed herein proved useful for detecting the environmental occurrence ofLeishmaniaspp. andL. chagasi, as well as determining natural wild reservoirs and contributing to understand the host-parasite interaction.

Road-killed animal; Leishmaniaspp; Leishmania chagasi; PCR; Zoonosis

Background

Leishmaniosis is a zoonotic, parasitic disease caused by kinetoplastid flagellate protozoan parasites of the genusLeishmaniathat infects several mammal species, including humans, and is transmitted by the phlebotomine sandfly.Leishmaniaspecies include visceral, cutaneous and mucocutaneous forms of the disease in both the Old and New Worlds [¹1 Gontijo B, Carvalho MLR: Leishmaniose tegumentar americana.Rev Soc Bras Med Trop2003, 36(1):71-80.,²2 Gontijo CMF, Melo MN: Leishmaniose visceral no Brazil: quadro atual, desafios e perspectivas. Rev Bras Epidemiol2004, 7(3):338-349.].

Great concern has been sparked by the contribution that global warming might be making to the recent increase in the number of reported cases and geographical areas [³3 Desjeux P: Leishmaniasis: currents situation and new perspectives. Comp Immunol Microbiol Infect Dis2004, 27(5):305-318.]. Environmental, demographic and human behavioral factors contribute to the changing landscape of leishmaniasis, which includes increased risk factors for zoonotic cutaneous leishmaniasis and new scenarios associated with the zoonotic visceral leishmaniasis [⁴4 Gramiccia M, Gradoni L: The current status of zoonotic leishmaniases and approaches to disease control. Int J Parasitol2005, 35(11–12):1169-1180.].

Studies onLeishmaniaspp. in wild animals have become more numerous in Brazil due to the importance of these species in the life cycle of leishmaniasis [⁵5 Luppi MM, Malta MC, Silva TM, Silva FL, Motta RO, Miranda I, Ecco R, Santos RL: Visceral leishmaniasis in captive wild canids in Brazil.Vet Parasitol2008, 155(1–2):146-151.]. Studies involving road-killed instead of laboratory research animals have become more frequent in helminthological, epidemiological, morphological and genetic areas [⁶6 Coyner DF, Wooding JB, Forrester DJ: A comparison of parasitic helminths and arthropods from two subspecies of fox squirrels (Sciurus niger) in Florida. J Wildl Dis1996, 32(3):492-497.

7 Cheadle MA, Tanhauser SM, Dame JB, Sellon DC, Hines M, Ginn PE, Mackay RJ, Greiner EC:The nine-banded armadillo (Dasypus novemcinctus) is an intermediate host forSarcocystis neurona. Int J Parasitol2001, 31(4):330-335.

8 Foster GW, Main MB, Kinsella JM, Dixon LM, Terrell SP, Forrester DJ: Parasitic helminths and arthropods of coyotes (Canis latrans) from Florida. USA Comp Parasitol2003, 70(2):162-166.

9 Nelder MP, Reeves WK: Ectoparasites of road-killed vertebrates in northwestern South Carolina, USA. Vet Parasitol2005, 129(3–4):313-322.

10 Ferroglio E, Ragagli C, Trisciuoglio A: Physaloptera sibirica in foxes and badgers from the Western Alps (Italy). Vet Parasitol2009, 163(1–2):164-166.

11 Hoppe EG, Araújo de Lima RC, Tebaldi JH, Athayde AC, Nascimento AA: Helminthological records of six-banded armadillos Euphractus sexcinctus (Linnaeus, 1758) from the Brazilian semi-arid region, Patos county, Paraíba state, including new morphological data on Trichohelix tuberculata (Parona and Stossich, 1901) Ortlepp, 1922 and proposal of Hadrostrongylus ransomi nov. comb. Braz J Biol2009, 69(2):423-428.-¹²12 Miquel J, Foronda P, Torres J, Swiderski Z, Feliu C: Ultrastructural study of the spermatozoon ofTaenia taeniaeformis(Batsch, 1786) (Cestoda, Cyclophyllidea, Taeniidae), an intestinal parasite ofFelis catusfrom La Palma (Canary Islands, Spain). Parasitol Res2009, 104(6):1477-1483.]. However, the use of molecular techniques for detection of microorganisms in these samples is recent [¹³13 Richini-Pereira VB, Bosco SMG, Griese J, Theodoro RC, Macoris SA, da Silva RJ, Barrozo L, Tavares PM, Zancopé-Oliveira RM, Bagagli E: Molecular detection ofParacoccidioides brasiliensisin road-killed wild animals. Med Mycol2008, 46(1):35-40.

14 Richini-Pereira VB, Bosco SMG, Theodoro RC, Barrozo L, Pedrini SCB, Rosa PS, Bagagli E:Importance of xenarthrans in the eco-epidemiology ofParacoccidioides brasiliensis. BMC Res Notes2009, 2:1-6.

15 Richini-Pereira VB, Bosco SMG, Theodoro RC, Barrozo L, Bagagli E: Road-killed wild animals: a preservation problem useful for eco-epidemiological studies of pathogens. J Venom Anim Toxins incl Trop Dis2010, 16(4):607613. http://www.scielo.br/scielo.php?script=sci_arttext&pid=S1678-91992010000400011webcite
http://www.scielo.br/scielo.php?script=s...

16 Zhao C, Onuma M, Asakawa M, Nagamine T, Kuwana T: Preliminary studies on developing a nested PCR assay for molecular diagnosis and identification of nematode (Heterakis isolonche) and trematode (Glaphyrostomumsp.) in Okinawa rail (Gallirallus okinawae). Vet Parasitol2009, 163(1–2):156-160.-¹⁷17 Pedrini SC, Rosa PS, Medri IM, Mourão G, Bagagli E, Lopes CA: Search forMycobacterium lepraein wild mammals.Braz J Infect Dis2010, 14(1):47-53.].

Despite the difficulty of culturing and histopathologically analyzing tissue samples from road-killed animals, molecular techniques can be used in the identification and typing of pathogens by polymerase chain reaction (PCR), which presents high specificity and sensitivity to a certain fragment of the pathogen’s specific DNA [¹⁸18 Persing DH, Smith TF, Tenover FC, White TJ:Diagnostic Molecular Microbiology: Principles and Applications. Washington, D.C: American Society for Microbiology; 1993:423-430.].

Leishmania kinetoplastic DNA (kDNA)-specific probes have been used for the detection and identification of this protozoan, and demonstrated to be useful for epidemiological field studies because a large number of samples can be handled simultaneously [¹⁹19 Esseghir SA, Ftaiti A, Ready PB, Khdraoui B, Zaafouri K, Dellagi K, Ben Ismail R: The squash blot technique and the detection ofLeishmania majorinPhlebotomus papatasiin Tunisia.Arch Inst Pasteur Tunis1993, 70(3–4):493-496.]. A minicircle of kDNA (0.8 to 1 kb in length) is an ideal target, since it is present in 10,000 copies per cell and because its sequences are known for mostLeishmaniaspecies [²⁰20 Aransay AM, Scoulica E, Tselentis Y: Detection and identification ofLeishmaniaDNA within naturally infected sand flies by seminested PCR on minicircle kinetoplastic DNA. Appl Environ Microbiol2000, 66(55):1933-1938.].

The present work aimed to describe possible new hosts for leishmaniasis by using molecular tools to detectLeishmaniaspp. in tissues of road-killed wild mammals. Thus, research into new hosts by molecular techniques is distinctive in epidemiological studies of pathogens and represents suitable indicators of environmental contamination byLeishmaniaspp. [²¹21 Gennari SM, Canón-Franco WA, Yai LE, de Souza SL, Santos LC, Farias NA, Ruas J, Rossi FW, Gomes AB: Seroprevalence ofToxoplasma gondiiantibodies from wild canids from Brazil. Vet Parasitol2004, 121(3–4):337-340.].

Methods

Animals and studied area

Seventy road-killed wild animals were studied: oneCallithrix penicillata(black-tufted marmoset), fourCavia aperea(Brazilian guinea pig), oneCebus apella(capuchin monkey), 13Cerdocyon thous(crab-eating fox), threeDasypus novemcinctus(nine-banded armadillo), oneDasypus septemcinctus(seven-banded armadillo), nineDidelphis albiventris(white-eared opossum), oneEira barbara(tayra), oneEuphractus sexcinctus(six-banded armadillo), twoGallictis vittata(grison), twoHydrochoerus hydrochaeris(capybara), oneLeopardus tigrinus(leopard cat), fiveLepus europaeus(brown hare), threeLutreolina crassicaudata(latrine opossum), twoMazama gouazoubira(brown brocket deer), oneMyocastor coypus(coypu), sixMyrmecophaga tridactyla(giant anteater), threeProcyon cancrivorus(crab-eating raccoon), twoPuma concolor(cougar), twoRattus rattus(black rat), fiveSphiggurus spinosus(porcupine) and twoTamandua tetradactyla(lesser anteater). Only recently killed animals (1–7 hours) and those with no exposed viscera were collected. This study is in accordance with the Brazilian Institute of Environment and Renewable Natural Resources’ (IBAMA) normative statement n. 119 of October 11, 2006, chapter VI, art .26, which authorizes the collection and transport of animals that were found dead for scientific or didactic purposes. This work was also approved by the Ethics Committee for Animal Experimentation at our Institution (CEEA/FMVZ n.211/2008).

The geographic positions of the road-killed animals, established through global positioning system (GPS), were plotted on a digital map using a geographic database by the TerraView 3.6.0 [²²22 INPE: Instituto Nacional de Pesquisas Espaciais. TerraView: Software; v.3.6.0 [http://www.dpi.inpe.br/terraview/index.phpwebcite]
http://www.dpi.inpe.br/terraview/index.p... ].

Molecular detection

DNA extraction from the animals’ tissue samples (lung, spleen, liver, kidney, heart, mesenteric lymph node and adrenal gland) was carried out by using the kit Illustra™ Tissue & Cells Genomic Prep Mini Spin (GE Healthcare, USA). PCR reactions were performed by employing the primers LinR4 (5’-GGGTTGGTGTAAAATAGGG-3’) and Lin19 (5’-CAGAACGCCCCTACCCG-3’), described by Aransayet al. [²⁰20 Aransay AM, Scoulica E, Tselentis Y: Detection and identification ofLeishmaniaDNA within naturally infected sand flies by seminested PCR on minicircle kinetoplastic DNA. Appl Environ Microbiol2000, 66(55):1933-1938.], to amplify a 720 bp fragment. Samples positive forLeishmaniaspp. PCR were also assayed forLeishmania braziliensiscomplex andLeishmania mexicanacomplex [²³23 de Bruijn MH, Barker DC: Diagnosis of New World leishmaniasis: specific detection of species of theLeishmania braziliensiscomplex by amplification of kinetoplast DNA. Acta Trop1992, 52(1):45-58.,²⁴24 Eresh S, McCallum SM, Barker DC: Identification and diagnosis ofLeishmania mexicanacomplex isolates by polymerase chain reaction. Parasitololy1994, 109(Pt 4):423-433.]. Genus-specific primers forLeishmaniaspp. were used in order to identify the DNA of all possibleLeishmaniaspecies that cause visceral or cutaneous leishmaniasis. The cycling profile consisted of an initial denaturation at 95°C for three minutes, followed by 30 cycles at 95°C for 30 seconds, 63°C for 30 seconds and 72°C for one minute, and a final extension at 72°C for seven minutes. Positive controls were included in each assay and consisted of 10 ng of DNA extracted fromLeishmania major(MHOM/SU/1973/5-ASKH) andL. chagasi(MHOM/BR/2002/LPC-RPV). Negative controls were: ultrapure water and DNA fromT. cruzi(ColTryp 0032/MCAN/BR/2008/CAO) that were added to the mix-PCR. The PCR mixture was composed of 10 mM Tris HCl pH 8.0, 50 mM KCl, 1.5 mM MgCl₂, 0.2 mM dNTP, 10 ρmol of each primer, 0.2 units ofTaqDNA polymerase, and 10 ng DNA template.

The amplification ofLeishmania chagasiDNA was performed utilizing primers Lc14 (5’-CGCACGTTATATCTACAGGTTGAG-3’) and Lc15 (5’- TGTTTGGGATTGAGGTAATAGTGA-3’) on a 190 bp fragment, by using the following cycling profile: initial denaturation at 94°C for four minutes, 40 cycles of 94°C for 30 seconds, 59°C for 30 seconds, 72°C for 30 seconds, and 70°C for ten minutes. Positive controls were included in each assay and consisted of 10 ng of DNA extracted fromL. chagasi(MHOM/BR/2002/LPC-RPV). Negative controls were: ultrapure water and DNA fromT. cruzi(ColTryp 0032/MCAN/BR/2008/CAO) that were added to the mix-PCR. The PCR mixture was composed of 10 mM Tris HCl pH 8.0, 50 mM KCl, 1.5 mM MgCl₂, 0.2 mM dNTP, 10 ρmol of each primer, 0.5 units ofTaqDNA polymerase, and 10 ng DNA template.

Amplification was performed in a MasterCycler EP gradient (Eppendorf, USA). The sequence was analyzed by electrophoresis in 1.5% agarose with SYBR® safe DNA gel stained (Invitrogen, USA), and visualized in an image analyzer (GelDoc-It™ Imaging System – UVP, USA) by using VisonWorks®LS Software. Amplicons were purified by using ExoSap (USB, USA) and the sequencing reactions were carried out on both strands in a 3500 Genetic Analyzer (Applied Biosystems). The obtained sense and antisense sequences were visualized (Chromas 2.3 software, Technelysium Pty Ltd, Australia), aligned by the software MEGA 4 and compared with the NCBI database using BLASTn (Basic Local Alignment Tool for Nucleotide) [²⁵25 Tamura K, Dudley J, Nei M, Kumar S: MEGA4: Molecular Evolutionary Genetics Analysis (MEGA) software version 4.0. Mol Biol Evol2007, 24(8):1596-1599.].

Results and discussion

The present results draw attention to a very important source of research and emphasize the importance of using this biological resource in an epidemiological study of zoonotic infection.

One of the main problems in elucidating leishmaniasis epidemiology is to identify and confirm that a vertebrate host is a natural reservoir. The natural reservoirs are widely unknown because of the difficulties in capturing a sufficient number of wild animals and due to the techniques used in isolating and identifying the parasite.

This approach of using road-killed wild animals for the molecular detection ofLeishmaniaspp. may represent a useful alternative to the utilization of captured ones in research studies, as indicated by animal research ethics committees. In the present study, a great diversity of road-killed wild mammal species was found. Culture analysis and histopathology are difficult and laborious. Sensitive and specific molecular tools allow pathogens to be identified without the need of culturing.

In this paper, molecular detection ofLeishmaniaspp. andLeishmania chagasiwas attempted from several wildlife species using PCR. Several studies have reported the presence of this parasite in mammalian species, including rodents, carnivores, primates and marsupials [⁵5 Luppi MM, Malta MC, Silva TM, Silva FL, Motta RO, Miranda I, Ecco R, Santos RL: Visceral leishmaniasis in captive wild canids in Brazil.Vet Parasitol2008, 155(1–2):146-151.,²⁶26 Alexander B, Lozano C, Barker DC, McCann SH, Adler G: Detection ofLeishmania(Viannia)braziliensiscomplex in wild mammals from Colombian coffee plantations by PCR and DNA hybridization. Acta Trop1998, 69(1):41-50.

27 Travi BL, Osorio Y, Becerra MT, Adler GH: Dynamics ofLeishmania chagasiinfection in small mammals of the undisturbed and degraded tropical dry forests of northern Colombia.Trans R Soc Trop Med Hyg1998, 92(3):275-278.

28 Curi NHA, Miranda I, Talamoni AS: Serologic evidence ofLeishmaniainfection in free-ranging wild and domestic canids around a Brazilian National Park. Mem Inst Oswaldo Cruz2006, 101(1):99-101.-²⁹29 Papadogiannakis E, Spanakos G, Kontos V, Menounos PG, Tegos N, Vakalis N: Molecular detection ofLeishmania infantumin wild rodents (Rattus norvegicus) in Greece. Zoonoses Public Health2010, 57(7–8):23-25.].

Table 1contains the results of the PCR and identifies percentages of amplicon obtained in road-killed wild animals positive forLeishmaniaspp. andLeishmania chagasifrom deposited homologue DNA sequences, as determined by BLASTn analysis. Figure 1 illustrates the human cutaneous leishmaniasis data corresponding to the cases seen in the central western area of the state of São Paulo, Brazil, from 1998 to 2010 [³⁰30 Centro de Vigilância Epidemiológica: Leishmaniose tegumentar americana. Distribuição do número de casos de Leishmaniose Tegumentar por município provável de infecção. Estado de São Paulo, 1998–2012.http://www.cve.saude.sp.gov.br/htm/zoo/lta_lpi.htmwebcite
http://www.cve.saude.sp.gov.br/htm/zoo/l... ]. Figure 2 displays the human visceral leishmaniasis data corresponding to the cases seen in the central western area of the state of São Paulo, Brazil, from 1998 to 2010 and geographic location of the positive road-killed animals evaluated [³¹31 Centro de Vigilância Epidemiológica: Leishmaniose visceral americana. Distribuição do número de casos e óbitos de LVA segundo município e GVE de infecção. Estado de São Paulo 1998–2011. http://www.cve.saude.sp.gov.br/htm/zoo/lvah_lpi.htmwebcite
http://www.cve.saude.sp.gov.br/htm/zoo/l... ].

Thumbnail

Table 1
Data on road-killed wild animals, including the sex, tissue, PCR and sequencing results for molecular detection onLeishmaniaspp. andLeishmania chagasi

Figure 1
Geographic location of road-killed animals employed forLeishmaniaspp. molecular detection, correlating to the occurrence of cases of human cutaneous leishmaniasis.

Figure 2
Geographic location of the road-killed animals employed forLeishmaniaspp. molecular detection, correlating to the occurrence of cases of human visceral leishmaniasis.

Leishmania DNA was detected in 5/12 (41.67%; CI95% 19.22-68.42%) samples fromCerdocyon thous(crab-eating fox). A previous report indicates seropositivity in wild non-captiveCerdocyon thous[⁵5 Luppi MM, Malta MC, Silva TM, Silva FL, Motta RO, Miranda I, Ecco R, Santos RL: Visceral leishmaniasis in captive wild canids in Brazil.Vet Parasitol2008, 155(1–2):146-151.,²⁸28 Curi NHA, Miranda I, Talamoni AS: Serologic evidence ofLeishmaniainfection in free-ranging wild and domestic canids around a Brazilian National Park. Mem Inst Oswaldo Cruz2006, 101(1):99-101.]. The importance of these animals as reservoirs depends on their ability to transmit the infection to sandflies rather than on their infection rate; it is also a function of their capability to (re)introduce the pathogen intoLeishmania-free dog populations [³²32 Dressen DW:Toxoplasma gondiiinfections in wildlife. J Am Vet Med Assoc1990, 196:274-276.].

In the current study,Leishmaniaspp. DNA was detected in 1/3Procyon cancrivorus(crab-eating raccoon). Voltarelliet al.[³³33 Voltarelli EM, Arraes SMAA, Perles TF, Lonardoni MVC, Teodoro U, Silveira TGV:Serological survey forLeishmaniasp. infection in wild animals from the municipality of Maringá, Paraná State, Brazil. J Venom Anim Toxins incl Trop Dis2009, 15(4):732-744. http://www.scielo.br/scielo.php?script=sci_arttext&pid=S1678-91992009000400011webcite
http://www.scielo.br/scielo.php?script=s... ] reported the presence ofLeishmaniaantibodies inProcyon cancrivorusin Northwestern Paraná. These findings suggest that these species can act as a reservoir forLeishmaniaspp.

The members of Didelphidae, represented byDidelphis albiventrisspecimens (white-eared opossums), are habitat generalists and currently occur in areas near dwellings, including farms, yards and urban centers [³⁴34 Câmara T, Murta R:Mamíferos da Serra do Cipó. PUC, Minas, Museu de Ciências Naturais: Belo Horizonte; 2003.]. This species is already proven to be a leishmaniasis reservoir and, for its synanthropic habits, it plays an important role in the peridomestic-forest traffic of degraded areas [³⁵35 Forrester DJ:Parasites and Diseases of Wild Mammals in Florida. First edition. Gainesville: University Press of Florida; 1992:459.

36 Guerra JAO, Ribeiro JAS, Coelho LIARC, Barbosa MGV, Paes MG: Epidemiologia da leishmaniose tegumentar na comunidade São João, Manaus, Amazonas. Brasil Cad Saúde Pública2006, 22(11):2319-2327.-³⁷37 Quintal AP, Ribeiro Ede S, Rodrigues FP, Rocha FS, Floeter-Winter LM, Nunes CM:Leishmaniaspp. inDidelphis albiventrisandMicoureus paraguayanus(Didelphimorphia: Didelphidae) of Brazil. Vet Parasitol2011, 176(2–3):112-119.]. The present study confirms that molecular detection ofLeishmaniaspp. in 2/8 group members may be common, as was already described in several regions of Brazil: Manaus, Amazonas state; in Barra de Guarituba, Rio de Janeiro state; in Amaraji, Pernambuco; and Bauru, São Paulo state [³⁸38 Arias JR, Naiff RD: The principal reservoir host of cutaneous leishmaniasis in the urban areas of Manaus, Central Amazon of Brazil.Mem Inst Oswaldo Cruz1981, 76(3):279-286.

39 Cabrera MAA, Paula AA, Camacho LAB, Marzochi MCA, Xavier SC, da Silva AVM, Jansen AM: Canine visceral leishmaniasis in Barra de Guaratiba, Rio de Janeiro, Brazil: assessment of risk factors. Rev Inst Med Trop Sao Paulo2003, 45(2):79-83.

40 Brandão-Filho SP, Brito ME, Carvalho FG, Ishikawa EA, Cupolillo E, Floeter-Winter L, Shaw JJ: Wild and synanthropic host ofLeishmania(Viannia)braziliensisin the endemic cutaneous leismaniasis locality of Amaraji, Pernambuco State, Brazil. Trans R Soc Trop Med Hyg2003, 97(3):291-296.-⁴¹41 Santiago ME, Vasconcelos RO, Fattori KR, Munari DP, Michelin Ade F, Lima VM: An investigation ofLeishmaniaspp. inDidelphisspp. from urban and peri-urban areas in Bauru (São Paulo, Brazil). Vet Parasitol2007, 150(4):283-290.].

Rodents were represented by fiveS. spinosus(porcupine), fourC. aperea(Brazilian guinea pig), twoRattus rattus(black rat), twoHydrochoerus hydrochaeris(capybara) and oneM. coypus(coypu). Current data show that 8/14 (57.14%; CI95% 35.14-82.34%) specimens of wild rodents were positive, a finding that corroborates the literature that considered some rodent as reservoirs ofLeishmaniaspp.

The superorder Xenarthra was represented by 13 specimens: threeD. novemcinctus(nine-banded armadillo), oneE. sexcinctus(six-banded armadillo), oneD. septemcinctus(seven-banded armadillo), twoT. tetradactyla(lesser anteater) and sixM. tridactyla(giant anteater). These animals present some peculiar physiological and ecological characteristics including a weak immune system and low body temperature, besides the fact that they live literally immersed in soil and organic matter, mainly in tropical and subtropical regions, under biotic and abiotic conditions that promote multiple encounters with a diverse group of pathogens and vectors.

The present study confirms the occurrence ofLeishmaniaspp. DNA in armadillos (oneD. septemcintus) and anteaters (oneT. tetradactylaand twoM. tridactyla). Casadeval and Pirofski[⁴²42 Casadevall A, Pirofski LA: Host-pathogen interactions: redefining the basic concepts of virulence and pathogenicity. Infect Immun1999, 67(8):3703-3713.] clarified many points on virulence and pathogenicity regarding host immune response and pathogen activity. According to the authors, there are classes of pathogenic microorganisms varying from those that provoke damage in hosts that present an extremely weak immune response to others that cause disease only in a situation of very strong immune response. Therefore, it seems reasonable to considerLeishmaniaspp. to be a pathogen whose ability to provoke disease also depends on host immune response. Since the cellular immune response is weak in armadillos and anteaters, it is possible to detect yeast cells in many of their organs; however, this is not sufficient to cause disease as observed in human hosts. Taken together, these factors make xenarthrans suitable models for studying host-pathogen interaction [⁴³43 Bagagli E, Bosco SMG: Armadillos and dimorphic pathogenic fungi: ecological and evolutionary aspects. InThe Biology of the Xenarthra. First edition. Edited by Viscaino SF, Loughry WJ. Gainesville: University Press of Florida; 2008:103-110.].

These animals are assumed to be sources of infection since the agent’s DNA was found in internal organs; in addition, parasitism may occur in internal and cutaneous organs, facilitating transmission from the blood meal by the vector that inoculates promastigote forms of the agent into the man while sucking.

The identities of the amplicon were confirmed by direct double-strand sequencing which showed 100% similarity withL. chagasisequence deposited at GenBank (access number AF308682.1) (Table 1).

Even without the DNA detection of the cutaneous leishmaniasis agents, the positive results forLeishmaniaspp. are interesting. Of the 20 species described in the New World, five have never been reported to have caused visceral human leishmaniasis:Leishmania enriettii, Leishmania hertigi, Leishmania deanei, Leishmania aristidesiandLeishmania forattinii[⁴⁴44 Muniz J, Medina HSG: Leishmaniose tegumentar do cobaio(Leishmania enriettii). Arq Biol Tecnol 1948, 3(2):7–25.

45 Herrer A:Leishmania hertigisp. n., from the tropical porcupine,Coendou rothschildi Thomas. J Parasitol1971, 57(3):626-629.

46 Lainson R, Shaw JJ: Leishmanias of neotropical porcupines:Leishmania hertigi deaneinov. subsp.Acta Amaz1977, 7(1):51-57.

47 Lainson R, Shaw JJ: The role of animals in the epidemiology of South American leishmaniasis. InThe Biology of the Kinetoplastida, Volume 2. Edited by Lumsden WHR, Evans DA. London, New York, San Francisco: Academic Press; 1979:1-116.-⁴⁸48 Yoshida ELA, Silva R, Cortez LS, Corrêa FMA: Encontro de espécie do gêneroLeishmaniaemDidelphis marsupialis auritano Estado de São Paulo, Brasil. Rev Inst Med Trop Sao Paulo1979, 21:110-113.]. TheL. forattiniiwas isolated from pooled liver and spleen of opossumDidelphis marsupialiscaptured in Conchas, SP, Brazil [⁴⁸48 Yoshida ELA, Silva R, Cortez LS, Corrêa FMA: Encontro de espécie do gêneroLeishmaniaemDidelphis marsupialis auritano Estado de São Paulo, Brasil. Rev Inst Med Trop Sao Paulo1979, 21:110-113.,⁴⁹49 Yoshida ELA, Cuba CA, Pacheco RS, Cupolillo E, Tavares CC, Machado GMC, Momen H, Grimaldi JG: Description ofLeishmania (Leishmania) forattiniisp. n., a new parasite infecting opossums and rodents in Brazil. Mem Inst Oswaldo Cruz1993, 88(3):397-406.].

It is suggested that the species isLeishmania forattiniiand that the evaluated site is close to that where the parasite was first isolated, since the species nucleotide sequence deposited at the GenBank was not found. Considering the occurrence of both the cutaneous and visceral form, in the studied municipalities, it must be emphasized that the sandfly vector may be present and serve as transmitter ofLeishmaniato these animals and humans.

These findings corroborate the worldwide distribution ofLeishmaniaspp., considering the wide variety of intermediate hosts that contribute to the epidemiological transmission chain of this infection.

It is important to emphasize that Bauru, SP, is endemic for leishmaniasis; therefore, our results indicate the need for epidemiological molecular biology research on environmental contamination byL. chagasi.

It was possible to evaluate 22 different wild species, without the necessity of exerting a laborious sampling effort. In fact, the numbers and diversity of road-killed animals are considerably higher and, in general, they are killed after their own natural habitats had been invaded by roads [⁵⁰50 Laurance WF, Goosem M, Laurance SG: Impacts of roads and linear clearings on tropical forests. Trends Ecol Evol2009, 24(12):659-669.]. In this manner, the geographic coordinates of the locations of the infected animals are well-integrated in databases that use the geographical information systems (GIS), thus contributing to a better understanding of pathogen distribution.

These results show risk factors such as free movement of the circulating parasite and vectors, as well as the importance of road-killed animals as possible reservoirs for the transmission ofLeishmaniaspp. in addition to the significance of the environment and ecology of these positive mammals in the interaction of Leishmania with differentLeishmaniaspecies that may be pathogenic to humans.

Conclusions

The presented results focus that road-killed animals may serve as an important reservoir for transmission ofLeishmaniaspp. andL. chagasi, as well as contributing to understand the host-parasite interaction.

Acknowledgments

The authors would like to thank the State of São Paulo Research Foundation (FAPESP, grants n. 08/09378-8 and n. 08/08291-6) for their funding of this research.

References

¹
Gontijo B, Carvalho MLR: Leishmaniose tegumentar americana.Rev Soc Bras Med Trop2003, 36(1):71-80.
²
Gontijo CMF, Melo MN: Leishmaniose visceral no Brazil: quadro atual, desafios e perspectivas. Rev Bras Epidemiol2004, 7(3):338-349.
³
Desjeux P: Leishmaniasis: currents situation and new perspectives. Comp Immunol Microbiol Infect Dis2004, 27(5):305-318.
⁴
Gramiccia M, Gradoni L: The current status of zoonotic leishmaniases and approaches to disease control. Int J Parasitol2005, 35(11–12):1169-1180.
⁵
Luppi MM, Malta MC, Silva TM, Silva FL, Motta RO, Miranda I, Ecco R, Santos RL: Visceral leishmaniasis in captive wild canids in Brazil.Vet Parasitol2008, 155(1–2):146-151.
⁶
Coyner DF, Wooding JB, Forrester DJ: A comparison of parasitic helminths and arthropods from two subspecies of fox squirrels (Sciurus niger) in Florida. J Wildl Dis1996, 32(3):492-497.
⁷
Cheadle MA, Tanhauser SM, Dame JB, Sellon DC, Hines M, Ginn PE, Mackay RJ, Greiner EC:The nine-banded armadillo (Dasypus novemcinctus) is an intermediate host forSarcocystis neurona Int J Parasitol2001, 31(4):330-335.
⁸
Foster GW, Main MB, Kinsella JM, Dixon LM, Terrell SP, Forrester DJ: Parasitic helminths and arthropods of coyotes (Canis latrans) from Florida. USA Comp Parasitol2003, 70(2):162-166.
⁹
Nelder MP, Reeves WK: Ectoparasites of road-killed vertebrates in northwestern South Carolina, USA. Vet Parasitol2005, 129(3–4):313-322.
¹⁰
Ferroglio E, Ragagli C, Trisciuoglio A: Physaloptera sibirica in foxes and badgers from the Western Alps (Italy). Vet Parasitol2009, 163(1–2):164-166.
¹¹
Hoppe EG, Araújo de Lima RC, Tebaldi JH, Athayde AC, Nascimento AA: Helminthological records of six-banded armadillos Euphractus sexcinctus (Linnaeus, 1758) from the Brazilian semi-arid region, Patos county, Paraíba state, including new morphological data on Trichohelix tuberculata (Parona and Stossich, 1901) Ortlepp, 1922 and proposal of Hadrostrongylus ransomi nov. comb. Braz J Biol2009, 69(2):423-428.
¹²
Miquel J, Foronda P, Torres J, Swiderski Z, Feliu C: Ultrastructural study of the spermatozoon ofTaenia taeniaeformis(Batsch, 1786) (Cestoda, Cyclophyllidea, Taeniidae), an intestinal parasite ofFelis catusfrom La Palma (Canary Islands, Spain). Parasitol Res2009, 104(6):1477-1483.
¹³
Richini-Pereira VB, Bosco SMG, Griese J, Theodoro RC, Macoris SA, da Silva RJ, Barrozo L, Tavares PM, Zancopé-Oliveira RM, Bagagli E: Molecular detection ofParacoccidioides brasiliensisin road-killed wild animals. Med Mycol2008, 46(1):35-40.
¹⁴
Richini-Pereira VB, Bosco SMG, Theodoro RC, Barrozo L, Pedrini SCB, Rosa PS, Bagagli E:Importance of xenarthrans in the eco-epidemiology ofParacoccidioides brasiliensis BMC Res Notes2009, 2:1-6.
¹⁵
Richini-Pereira VB, Bosco SMG, Theodoro RC, Barrozo L, Bagagli E: Road-killed wild animals: a preservation problem useful for eco-epidemiological studies of pathogens. J Venom Anim Toxins incl Trop Dis2010, 16(4):607613. http://www.scielo.br/scielo.php?script=sci_arttext&pid=S1678-91992010000400011webcite
» http://www.scielo.br/scielo.php?script=sci_arttext&pid=S1678-91992010000400011
¹⁶
Zhao C, Onuma M, Asakawa M, Nagamine T, Kuwana T: Preliminary studies on developing a nested PCR assay for molecular diagnosis and identification of nematode (Heterakis isolonche) and trematode (Glaphyrostomumsp.) in Okinawa rail (Gallirallus okinawae). Vet Parasitol2009, 163(1–2):156-160.
¹⁷
Pedrini SC, Rosa PS, Medri IM, Mourão G, Bagagli E, Lopes CA: Search forMycobacterium lepraein wild mammals.Braz J Infect Dis2010, 14(1):47-53.
¹⁸
Persing DH, Smith TF, Tenover FC, White TJ:Diagnostic Molecular Microbiology: Principles and Applications Washington, D.C: American Society for Microbiology; 1993:423-430.
¹⁹
Esseghir SA, Ftaiti A, Ready PB, Khdraoui B, Zaafouri K, Dellagi K, Ben Ismail R: The squash blot technique and the detection ofLeishmania majorinPhlebotomus papatasiin Tunisia.Arch Inst Pasteur Tunis1993, 70(3–4):493-496.
²⁰
Aransay AM, Scoulica E, Tselentis Y: Detection and identification ofLeishmaniaDNA within naturally infected sand flies by seminested PCR on minicircle kinetoplastic DNA. Appl Environ Microbiol2000, 66(55):1933-1938.
²¹
Gennari SM, Canón-Franco WA, Yai LE, de Souza SL, Santos LC, Farias NA, Ruas J, Rossi FW, Gomes AB: Seroprevalence ofToxoplasma gondiiantibodies from wild canids from Brazil. Vet Parasitol2004, 121(3–4):337-340.
²²
INPE: Instituto Nacional de Pesquisas Espaciais. TerraView: Software; v.3.6.0 [http://www.dpi.inpe.br/terraview/index.phpwebcite]
» http://www.dpi.inpe.br/terraview/index.php
²³
de Bruijn MH, Barker DC: Diagnosis of New World leishmaniasis: specific detection of species of theLeishmania braziliensiscomplex by amplification of kinetoplast DNA. Acta Trop1992, 52(1):45-58.
²⁴
Eresh S, McCallum SM, Barker DC: Identification and diagnosis ofLeishmania mexicanacomplex isolates by polymerase chain reaction. Parasitololy1994, 109(Pt 4):423-433.
²⁵
Tamura K, Dudley J, Nei M, Kumar S: MEGA4: Molecular Evolutionary Genetics Analysis (MEGA) software version 4.0. Mol Biol Evol2007, 24(8):1596-1599.
²⁶
Alexander B, Lozano C, Barker DC, McCann SH, Adler G: Detection ofLeishmania(Viannia)braziliensiscomplex in wild mammals from Colombian coffee plantations by PCR and DNA hybridization. Acta Trop1998, 69(1):41-50.
²⁷
Travi BL, Osorio Y, Becerra MT, Adler GH: Dynamics ofLeishmania chagasiinfection in small mammals of the undisturbed and degraded tropical dry forests of northern Colombia.Trans R Soc Trop Med Hyg1998, 92(3):275-278.
²⁸
Curi NHA, Miranda I, Talamoni AS: Serologic evidence ofLeishmaniainfection in free-ranging wild and domestic canids around a Brazilian National Park. Mem Inst Oswaldo Cruz2006, 101(1):99-101.
²⁹
Papadogiannakis E, Spanakos G, Kontos V, Menounos PG, Tegos N, Vakalis N: Molecular detection ofLeishmania infantumin wild rodents (Rattus norvegicus) in Greece. Zoonoses Public Health2010, 57(7–8):23-25.
³⁰
Centro de Vigilância Epidemiológica: Leishmaniose tegumentar americana. Distribuição do número de casos de Leishmaniose Tegumentar por município provável de infecção. Estado de São Paulo, 1998–2012.http://www.cve.saude.sp.gov.br/htm/zoo/lta_lpi.htmwebcite
» http://www.cve.saude.sp.gov.br/htm/zoo/lta_lpi.htm
³¹
Centro de Vigilância Epidemiológica: Leishmaniose visceral americana. Distribuição do número de casos e óbitos de LVA segundo município e GVE de infecção. Estado de São Paulo 1998–2011. http://www.cve.saude.sp.gov.br/htm/zoo/lvah_lpi.htmwebcite
» http://www.cve.saude.sp.gov.br/htm/zoo/lvah_lpi.htm
³²
Dressen DW:Toxoplasma gondiiinfections in wildlife. J Am Vet Med Assoc1990, 196:274-276.
³³
Voltarelli EM, Arraes SMAA, Perles TF, Lonardoni MVC, Teodoro U, Silveira TGV:Serological survey forLeishmaniasp. infection in wild animals from the municipality of Maringá, Paraná State, Brazil. J Venom Anim Toxins incl Trop Dis2009, 15(4):732-744. http://www.scielo.br/scielo.php?script=sci_arttext&pid=S1678-91992009000400011webcite
» http://www.scielo.br/scielo.php?script=sci_arttext&pid=S1678-91992009000400011
³⁴
Câmara T, Murta R:Mamíferos da Serra do Cipó PUC, Minas, Museu de Ciências Naturais: Belo Horizonte; 2003.
³⁵
Forrester DJ:Parasites and Diseases of Wild Mammals in Florida First edition. Gainesville: University Press of Florida; 1992:459.
³⁶
Guerra JAO, Ribeiro JAS, Coelho LIARC, Barbosa MGV, Paes MG: Epidemiologia da leishmaniose tegumentar na comunidade São João, Manaus, Amazonas. Brasil Cad Saúde Pública2006, 22(11):2319-2327.
³⁷
Quintal AP, Ribeiro Ede S, Rodrigues FP, Rocha FS, Floeter-Winter LM, Nunes CM:Leishmaniaspp. inDidelphis albiventrisandMicoureus paraguayanus(Didelphimorphia: Didelphidae) of Brazil. Vet Parasitol2011, 176(2–3):112-119.
³⁸
Arias JR, Naiff RD: The principal reservoir host of cutaneous leishmaniasis in the urban areas of Manaus, Central Amazon of Brazil.Mem Inst Oswaldo Cruz1981, 76(3):279-286.
³⁹
Cabrera MAA, Paula AA, Camacho LAB, Marzochi MCA, Xavier SC, da Silva AVM, Jansen AM: Canine visceral leishmaniasis in Barra de Guaratiba, Rio de Janeiro, Brazil: assessment of risk factors. Rev Inst Med Trop Sao Paulo2003, 45(2):79-83.
⁴⁰
Brandão-Filho SP, Brito ME, Carvalho FG, Ishikawa EA, Cupolillo E, Floeter-Winter L, Shaw JJ: Wild and synanthropic host ofLeishmania(Viannia)braziliensisin the endemic cutaneous leismaniasis locality of Amaraji, Pernambuco State, Brazil. Trans R Soc Trop Med Hyg2003, 97(3):291-296.
⁴¹
Santiago ME, Vasconcelos RO, Fattori KR, Munari DP, Michelin Ade F, Lima VM: An investigation ofLeishmaniaspp. inDidelphisspp. from urban and peri-urban areas in Bauru (São Paulo, Brazil). Vet Parasitol2007, 150(4):283-290.
⁴²
Casadevall A, Pirofski LA: Host-pathogen interactions: redefining the basic concepts of virulence and pathogenicity. Infect Immun1999, 67(8):3703-3713.
⁴³
Bagagli E, Bosco SMG: Armadillos and dimorphic pathogenic fungi: ecological and evolutionary aspects. InThe Biology of the Xenarthra First edition. Edited by Viscaino SF, Loughry WJ. Gainesville: University Press of Florida; 2008:103-110.
⁴⁴
Muniz J, Medina HSG: Leishmaniose tegumentar do cobaio(Leishmania enriettii) Arq Biol Tecnol 1948, 3(2):7–25.
⁴⁵
Herrer A:Leishmania hertigisp. n., from the tropical porcupine,Coendou rothschildi Thomas J Parasitol1971, 57(3):626-629.
⁴⁶
Lainson R, Shaw JJ: Leishmanias of neotropical porcupines:Leishmania hertigi deaneinov. subsp.Acta Amaz1977, 7(1):51-57.
⁴⁷
Lainson R, Shaw JJ: The role of animals in the epidemiology of South American leishmaniasis. InThe Biology of the Kinetoplastida, Volume 2 Edited by Lumsden WHR, Evans DA. London, New York, San Francisco: Academic Press; 1979:1-116.
⁴⁸
Yoshida ELA, Silva R, Cortez LS, Corrêa FMA: Encontro de espécie do gêneroLeishmaniaemDidelphis marsupialis auritano Estado de São Paulo, Brasil. Rev Inst Med Trop Sao Paulo1979, 21:110-113.
⁴⁹
Yoshida ELA, Cuba CA, Pacheco RS, Cupolillo E, Tavares CC, Machado GMC, Momen H, Grimaldi JG: Description ofLeishmania (Leishmania) forattiniisp. n., a new parasite infecting opossums and rodents in Brazil. Mem Inst Oswaldo Cruz1993, 88(3):397-406.
⁵⁰
Laurance WF, Goosem M, Laurance SG: Impacts of roads and linear clearings on tropical forests. Trends Ecol Evol2009, 24(12):659-669.

Ethics committee approval

This study is in accordance with the Brazilian Institute of Environment and Renewable Natural Resources’ (IBAMA) normative statement n. 119 of October 11, 2006, chapter VI, art .26, which authorizes the collection and transport of animals that were found dead for scientific or didactic purposes. This work was also approved by the Ethics Committee for Animal Experimentation of our Institution (CEEA/FMVZ n.211/2008).

Publication Dates

Publication in this collection
2014

History

Received
6 Jan 2014
Reviewed
4 June 2014
Accepted
16 June 2014

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ¹
Gontijo B, Carvalho MLR: Leishmaniose tegumentar americana.Rev Soc Bras Med Trop2003, 36(1):71-80.

[2] ²
Gontijo CMF, Melo MN: Leishmaniose visceral no Brazil: quadro atual, desafios e perspectivas. Rev Bras Epidemiol2004, 7(3):338-349.

[3] ³
Desjeux P: Leishmaniasis: currents situation and new perspectives. Comp Immunol Microbiol Infect Dis2004, 27(5):305-318.

[4] ⁴
Gramiccia M, Gradoni L: The current status of zoonotic leishmaniases and approaches to disease control. Int J Parasitol2005, 35(11–12):1169-1180.

[5] ⁵
Luppi MM, Malta MC, Silva TM, Silva FL, Motta RO, Miranda I, Ecco R, Santos RL: Visceral leishmaniasis in captive wild canids in Brazil.Vet Parasitol2008, 155(1–2):146-151.

[6] ⁶
Coyner DF, Wooding JB, Forrester DJ: A comparison of parasitic helminths and arthropods from two subspecies of fox squirrels (Sciurus niger) in Florida. J Wildl Dis1996, 32(3):492-497.

[7] ⁷
Cheadle MA, Tanhauser SM, Dame JB, Sellon DC, Hines M, Ginn PE, Mackay RJ, Greiner EC:The nine-banded armadillo (Dasypus novemcinctus) is an intermediate host forSarcocystis neurona Int J Parasitol2001, 31(4):330-335.

[8] ⁸
Foster GW, Main MB, Kinsella JM, Dixon LM, Terrell SP, Forrester DJ: Parasitic helminths and arthropods of coyotes (Canis latrans) from Florida. USA Comp Parasitol2003, 70(2):162-166.

[9] ⁹
Nelder MP, Reeves WK: Ectoparasites of road-killed vertebrates in northwestern South Carolina, USA. Vet Parasitol2005, 129(3–4):313-322.

[10] ¹⁰
Ferroglio E, Ragagli C, Trisciuoglio A: Physaloptera sibirica in foxes and badgers from the Western Alps (Italy). Vet Parasitol2009, 163(1–2):164-166.

[11] ¹¹
Hoppe EG, Araújo de Lima RC, Tebaldi JH, Athayde AC, Nascimento AA: Helminthological records of six-banded armadillos Euphractus sexcinctus (Linnaeus, 1758) from the Brazilian semi-arid region, Patos county, Paraíba state, including new morphological data on Trichohelix tuberculata (Parona and Stossich, 1901) Ortlepp, 1922 and proposal of Hadrostrongylus ransomi nov. comb. Braz J Biol2009, 69(2):423-428.

[12] ¹²
Miquel J, Foronda P, Torres J, Swiderski Z, Feliu C: Ultrastructural study of the spermatozoon ofTaenia taeniaeformis(Batsch, 1786) (Cestoda, Cyclophyllidea, Taeniidae), an intestinal parasite ofFelis catusfrom La Palma (Canary Islands, Spain). Parasitol Res2009, 104(6):1477-1483.

[13] ¹³
Richini-Pereira VB, Bosco SMG, Griese J, Theodoro RC, Macoris SA, da Silva RJ, Barrozo L, Tavares PM, Zancopé-Oliveira RM, Bagagli E: Molecular detection ofParacoccidioides brasiliensisin road-killed wild animals. Med Mycol2008, 46(1):35-40.

[14] ¹⁴
Richini-Pereira VB, Bosco SMG, Theodoro RC, Barrozo L, Pedrini SCB, Rosa PS, Bagagli E:Importance of xenarthrans in the eco-epidemiology ofParacoccidioides brasiliensis BMC Res Notes2009, 2:1-6.

[15] ¹⁵
Richini-Pereira VB, Bosco SMG, Theodoro RC, Barrozo L, Bagagli E: Road-killed wild animals: a preservation problem useful for eco-epidemiological studies of pathogens. J Venom Anim Toxins incl Trop Dis2010, 16(4):607613. http://www.scielo.br/scielo.php?script=sci_arttext&pid=S1678-91992010000400011webcite
» http://www.scielo.br/scielo.php?script=sci_arttext&pid=S1678-91992010000400011

[16] ¹⁶
Zhao C, Onuma M, Asakawa M, Nagamine T, Kuwana T: Preliminary studies on developing a nested PCR assay for molecular diagnosis and identification of nematode (Heterakis isolonche) and trematode (Glaphyrostomumsp.) in Okinawa rail (Gallirallus okinawae). Vet Parasitol2009, 163(1–2):156-160.

[17] ¹⁷
Pedrini SC, Rosa PS, Medri IM, Mourão G, Bagagli E, Lopes CA: Search forMycobacterium lepraein wild mammals.Braz J Infect Dis2010, 14(1):47-53.

[18] ¹⁸
Persing DH, Smith TF, Tenover FC, White TJ:Diagnostic Molecular Microbiology: Principles and Applications Washington, D.C: American Society for Microbiology; 1993:423-430.

[19] ¹⁹
Esseghir SA, Ftaiti A, Ready PB, Khdraoui B, Zaafouri K, Dellagi K, Ben Ismail R: The squash blot technique and the detection ofLeishmania majorinPhlebotomus papatasiin Tunisia.Arch Inst Pasteur Tunis1993, 70(3–4):493-496.

[20] ²⁰
Aransay AM, Scoulica E, Tselentis Y: Detection and identification ofLeishmaniaDNA within naturally infected sand flies by seminested PCR on minicircle kinetoplastic DNA. Appl Environ Microbiol2000, 66(55):1933-1938.

[21] ²¹
Gennari SM, Canón-Franco WA, Yai LE, de Souza SL, Santos LC, Farias NA, Ruas J, Rossi FW, Gomes AB: Seroprevalence ofToxoplasma gondiiantibodies from wild canids from Brazil. Vet Parasitol2004, 121(3–4):337-340.

[22] ²²
INPE: Instituto Nacional de Pesquisas Espaciais. TerraView: Software; v.3.6.0 [http://www.dpi.inpe.br/terraview/index.phpwebcite]
» http://www.dpi.inpe.br/terraview/index.php

[23] ²³
de Bruijn MH, Barker DC: Diagnosis of New World leishmaniasis: specific detection of species of theLeishmania braziliensiscomplex by amplification of kinetoplast DNA. Acta Trop1992, 52(1):45-58.

[24] ²⁴
Eresh S, McCallum SM, Barker DC: Identification and diagnosis ofLeishmania mexicanacomplex isolates by polymerase chain reaction. Parasitololy1994, 109(Pt 4):423-433.

[25] ²⁵
Tamura K, Dudley J, Nei M, Kumar S: MEGA4: Molecular Evolutionary Genetics Analysis (MEGA) software version 4.0. Mol Biol Evol2007, 24(8):1596-1599.

[26] ²⁶
Alexander B, Lozano C, Barker DC, McCann SH, Adler G: Detection ofLeishmania(Viannia)braziliensiscomplex in wild mammals from Colombian coffee plantations by PCR and DNA hybridization. Acta Trop1998, 69(1):41-50.

[27] ²⁷
Travi BL, Osorio Y, Becerra MT, Adler GH: Dynamics ofLeishmania chagasiinfection in small mammals of the undisturbed and degraded tropical dry forests of northern Colombia.Trans R Soc Trop Med Hyg1998, 92(3):275-278.

[28] ²⁸
Curi NHA, Miranda I, Talamoni AS: Serologic evidence ofLeishmaniainfection in free-ranging wild and domestic canids around a Brazilian National Park. Mem Inst Oswaldo Cruz2006, 101(1):99-101.

[29] ²⁹
Papadogiannakis E, Spanakos G, Kontos V, Menounos PG, Tegos N, Vakalis N: Molecular detection ofLeishmania infantumin wild rodents (Rattus norvegicus) in Greece. Zoonoses Public Health2010, 57(7–8):23-25.

[30] ³⁰
Centro de Vigilância Epidemiológica: Leishmaniose tegumentar americana. Distribuição do número de casos de Leishmaniose Tegumentar por município provável de infecção. Estado de São Paulo, 1998–2012.http://www.cve.saude.sp.gov.br/htm/zoo/lta_lpi.htmwebcite
» http://www.cve.saude.sp.gov.br/htm/zoo/lta_lpi.htm

[31] ³¹
Centro de Vigilância Epidemiológica: Leishmaniose visceral americana. Distribuição do número de casos e óbitos de LVA segundo município e GVE de infecção. Estado de São Paulo 1998–2011. http://www.cve.saude.sp.gov.br/htm/zoo/lvah_lpi.htmwebcite
» http://www.cve.saude.sp.gov.br/htm/zoo/lvah_lpi.htm

[32] ³²
Dressen DW:Toxoplasma gondiiinfections in wildlife. J Am Vet Med Assoc1990, 196:274-276.

[33] ³³
Voltarelli EM, Arraes SMAA, Perles TF, Lonardoni MVC, Teodoro U, Silveira TGV:Serological survey forLeishmaniasp. infection in wild animals from the municipality of Maringá, Paraná State, Brazil. J Venom Anim Toxins incl Trop Dis2009, 15(4):732-744. http://www.scielo.br/scielo.php?script=sci_arttext&pid=S1678-91992009000400011webcite
» http://www.scielo.br/scielo.php?script=sci_arttext&pid=S1678-91992009000400011

[34] ³⁴
Câmara T, Murta R:Mamíferos da Serra do Cipó PUC, Minas, Museu de Ciências Naturais: Belo Horizonte; 2003.

[35] ³⁵
Forrester DJ:Parasites and Diseases of Wild Mammals in Florida First edition. Gainesville: University Press of Florida; 1992:459.

[36] ³⁶
Guerra JAO, Ribeiro JAS, Coelho LIARC, Barbosa MGV, Paes MG: Epidemiologia da leishmaniose tegumentar na comunidade São João, Manaus, Amazonas. Brasil Cad Saúde Pública2006, 22(11):2319-2327.

[37] ³⁷
Quintal AP, Ribeiro Ede S, Rodrigues FP, Rocha FS, Floeter-Winter LM, Nunes CM:Leishmaniaspp. inDidelphis albiventrisandMicoureus paraguayanus(Didelphimorphia: Didelphidae) of Brazil. Vet Parasitol2011, 176(2–3):112-119.

[38] ³⁸
Arias JR, Naiff RD: The principal reservoir host of cutaneous leishmaniasis in the urban areas of Manaus, Central Amazon of Brazil.Mem Inst Oswaldo Cruz1981, 76(3):279-286.

[39] ³⁹
Cabrera MAA, Paula AA, Camacho LAB, Marzochi MCA, Xavier SC, da Silva AVM, Jansen AM: Canine visceral leishmaniasis in Barra de Guaratiba, Rio de Janeiro, Brazil: assessment of risk factors. Rev Inst Med Trop Sao Paulo2003, 45(2):79-83.

[40] ⁴⁰
Brandão-Filho SP, Brito ME, Carvalho FG, Ishikawa EA, Cupolillo E, Floeter-Winter L, Shaw JJ: Wild and synanthropic host ofLeishmania(Viannia)braziliensisin the endemic cutaneous leismaniasis locality of Amaraji, Pernambuco State, Brazil. Trans R Soc Trop Med Hyg2003, 97(3):291-296.

[41] ⁴¹
Santiago ME, Vasconcelos RO, Fattori KR, Munari DP, Michelin Ade F, Lima VM: An investigation ofLeishmaniaspp. inDidelphisspp. from urban and peri-urban areas in Bauru (São Paulo, Brazil). Vet Parasitol2007, 150(4):283-290.

[42] ⁴²
Casadevall A, Pirofski LA: Host-pathogen interactions: redefining the basic concepts of virulence and pathogenicity. Infect Immun1999, 67(8):3703-3713.

[43] ⁴³
Bagagli E, Bosco SMG: Armadillos and dimorphic pathogenic fungi: ecological and evolutionary aspects. InThe Biology of the Xenarthra First edition. Edited by Viscaino SF, Loughry WJ. Gainesville: University Press of Florida; 2008:103-110.

[44] ⁴⁴
Muniz J, Medina HSG: Leishmaniose tegumentar do cobaio(Leishmania enriettii) Arq Biol Tecnol 1948, 3(2):7–25.

[45] ⁴⁵
Herrer A:Leishmania hertigisp. n., from the tropical porcupine,Coendou rothschildi Thomas J Parasitol1971, 57(3):626-629.

[46] ⁴⁶
Lainson R, Shaw JJ: Leishmanias of neotropical porcupines:Leishmania hertigi deaneinov. subsp.Acta Amaz1977, 7(1):51-57.

[47] ⁴⁷
Lainson R, Shaw JJ: The role of animals in the epidemiology of South American leishmaniasis. InThe Biology of the Kinetoplastida, Volume 2 Edited by Lumsden WHR, Evans DA. London, New York, San Francisco: Academic Press; 1979:1-116.

[48] ⁴⁸
Yoshida ELA, Silva R, Cortez LS, Corrêa FMA: Encontro de espécie do gêneroLeishmaniaemDidelphis marsupialis auritano Estado de São Paulo, Brasil. Rev Inst Med Trop Sao Paulo1979, 21:110-113.

[49] ⁴⁹
Yoshida ELA, Cuba CA, Pacheco RS, Cupolillo E, Tavares CC, Machado GMC, Momen H, Grimaldi JG: Description ofLeishmania (Leishmania) forattiniisp. n., a new parasite infecting opossums and rodents in Brazil. Mem Inst Oswaldo Cruz1993, 88(3):397-406.

[50] ⁵⁰
Laurance WF, Goosem M, Laurance SG: Impacts of roads and linear clearings on tropical forests. Trends Ecol Evol2009, 24(12):659-669.

Species	Animal	Sex	Tissue (PCR positive)	% identity/GenBank access
Procyon cancrivorus	A1	Male	kidney	99%/AJ270142.1Leishmaniaspp.
Cerdocyon thous	A4	Male	heart, mesenteric lymph node	100%/AJ270142.1Leishmaniaspp.
Cerdocyon thous	A6	Male	spleen, heart	100%/AJ270142.1Leishmaniaspp.
Cerdocyon thous	A7	Male	heart	100%/AJ270141.1Leishmaniaspp.
Cavia aperea	A17	Male	heart	99%/AJ270141.1Leishmaniaspp.
Dasypus septemcinctus	A18	Male	liver	100%/AJ270141.1Leishmaniaspp.
Sphiggurus spinosus	A22	#	liver, spleen	100%/AJ270142.1Leishmaniaspp.
Tamandua tetradactyla	A23	Male	lung, liver, mesenteric lymph node	100%/AJ270142.1Leishmaniaspp.
Shiggurus spinosus	A24	Female	spleen, kidney, heart	100%/AJ270142.1Leishmaniaspp.
Cerdocyon thous	A41	Male	liver, mesenteric lymph node	100%/AF308682.1Leishmania chagasi
Myrmecophaga. tridactyla	A42	Male	lung, kidney, heart, mesenteric lymph node	100%/AJ270142.1Leishmaniaspp.
Didelphis albiventris	A46	Male	liver, spleen, kidney	100%/AJ270142.1Leishmaniaspp.
Didelphis albiventris	A47	Male	lung	100%/AJ270142.1Leishmaniaspp.
Hydrochoerus hydrochaeris	A50	Female	lung	100%/AJ270142.1Leishmaniaspp.
Cerdocyon thous	A54	Male	lung, spleen	100%/AJ270142.1Leishmaniaspp.
Myrmecophaga tridactyla	A60	Male	lung	100%/AJ270142.1Leishmaniaspp.