Abstract

Introduction

Tick-borne rickettsioses are zoonotic infections, with a global distribution, caused by intracellular bacteria belonging to genus Rickettsia (Parola et al., 2013Parola P, Paddock CD, Socolovschi C et al. (2013) Update on tick-borne rickettsioses around the world: a geographic approach. Clin Microbiol Rev 26:657–702.). Prior to 2004, the only tick-associated rickettsia species documented in Brazil was Rickettsia rickettsii, the etiological agent of Brazilian spotted fever (BSF). However, during the last decade an additional seven species (Rickettsia amblyommii, Rickettsia bellii, Rickettsia monteiroi, Rickettsia parkeri, Rickettsia rhipicephali, Rickettsia sp. Pampulha strain, and Candidatus Rickettsia andeanae) have been detected in a variety of tick species, parasitizing a range of hosts including wild birds and mammals (Labruna et al., 2011Labruna B, Mattar S, Nava S et al. (2011) Rickettsioses in Latin America, Caribbean, Spain and Portugal, Rev Med Vet Zootec Córd 16:2435–2457.; Parola et al., 2013Parola P, Paddock CD, Socolovschi C et al. (2013) Update on tick-borne rickettsioses around the world: a geographic approach. Clin Microbiol Rev 26:657–702.; Nieri-Bastos et al., 2014Nieri-Bastos FA, Lopes MG, Cançado PHD et al.(2014) Candidatus Rickettsia andeanae, a spotted fever group agent infecting Amblyomma parvum ticks in two Brazilian biomes Mem Inst Oswaldo Cruz 1–3.).

The tick, Amblyomma longirostre is widely distributed throughout Central and South America (Guglielmone et al., 2003Guglielmone AA, Estrada Peña A, Keirans JE et al.(2003). Ticks (Acari: Ixodida) of the Neotropical Zoogeographic Region. Special Publication, International Consortium on Ticks and Tick-Borne Diseases (ICTTD-2), Atalanta, Houten, The Netherlands, p. 173.; Barros-Battesti et al., 2006Barros-Battesti DM, Arzua M, Bechara GH (2006) Carrapatos de importância médicoveterinária da Região Neotropical: Um guia ilustrado para identificação de espécies, vol. 1. Butantan, São Paulo, p. 223.). Regarding the life cycle, adults are reported as predominantly infesting arboreal, neotropical porcupines of the family, Erethizontidae (Silveira et al., 2008Silveira JAG, Oliveira PA, Curi NHA et al. (2008) Ocorrência de Amblyomma longirostre (Koch, 1844) em Chaetomys subspinosus (Olfers, 1818) oriundos da Mata Atlântica. Arq Bras Med Vet Zootec 60:772–774.; Nava et al., 2010Nava S, Velazco PM, Guglielmone AA (2010) First record of Amblyomma longirostre (Koch, 1844) (Acari: Ixodidae) from Peru, with a review of this tick’s host relationships. Syst Appl Acarol 15:21–30.), while larval and nymphal stages have been found almost exclusively in association with passeriform birds, suggesting that it is an arboreal tick which inhabits the forest canopy (Labruna et al., 2007aLabruna MB, Wlippo LFS, Demetrio C et al. (2007a). Ticks collected on birds in the state of São Paulo, Brazil. Exp Appl Acarol 43:147–160.; Nava et al., 2010Nava S, Velazco PM, Guglielmone AA (2010) First record of Amblyomma longirostre (Koch, 1844) (Acari: Ixodidae) from Peru, with a review of this tick’s host relationships. Syst Appl Acarol 15:21–30.; Luz and Faccini, 2013Luz HR, Faccini JLH (2013) Ticks on Brazilian Birds: Overview. In Birds: Evolution and Behavior, Breeding Strategies, Migration and Spread of Disease. Nova Science Publishers Inc., NY, pp. 188.; Sanches et al., 2013; Torga et al., 2013Torga K, Tolesano-Pascoli G, Bonfim J et al. (2013) Ticks on birds from Cerrado forest patches along the Uberabinha river in the Triângulo Mineiro region of Minas Gerais, Brazil. Ciênc Rur 43:1852–1857.).

Studies investigating rickettsial infections in ticks parasitizing wild animals in the Northeast region of Brazil are scarce and have been restricted to the description of R. amblyommii in immature stages of A. longirostre collected from birds in the state of Bahia (Ogrzewalska et al., 2011aOgrzewalska M, Uezu A, Labruna MB (2011a) Ticks (Acari: Ixodidae) infesting wild birds in the Atlantic Forest in Northeastern Brazil, with notes on rickettsial infection in ticks. Parasitol Res 108:665–670.), and in immatures and adults of Amblyomma auricularium collected from the striped hog-nosed skunk (Conepatus semistriatus), and armadillos (Euphractus sexcinctus) in the state of Pernambuco (Saraiva et al., 2013Saraiva DG, Nieri-Bastos FA, Horta MC et al. (2013) Rickettsia amblyommii Infecting Amblyomma auricularium Ticks in Pernambuco, Northeastern Brazil: Isolation, Transovarial Transmission, and Transstadial Perpetuation. Vector-Borne and Zoo Dis 13:615–618.).

The current study reports tick infestations in two species of porcupines cohabiting remnants of Atlantic Forest in Southern Bahia, and provides details of molecular detection of rickettsial infections in adult A. longirostre.

Material and Methods

Ticks were collected, manually and/or using tweezers, from a total of 7 thin-spined porcupines (Chaetomys subspinosus) and from 6 hairy dwarf porcupines (Coendou insidiosus), captured in the Una Biological Reserve (Rebio-Una) and the Una Wildlife Refuge (Revis-Una) located in the municipality of Ilhéus (14°47′20″ S, 39°02′56″ W), Southern Bahia state, Northeast Brazil. All procedures were conducted with the legal approval and consent of the Brazilian Federal Authority (ICMBio, license numbers: 25184-1; 23468-2 and 27021-1).

Each tick was placed in an individual plastic flask containing 92% ethanol and transported within 24 hours to the laboratory in order to perform taxonomic identification procedures as proposed by Barros-Battesti et al. (2006)Barros-Battesti DM, Arzua M, Bechara GH (2006) Carrapatos de importância médicoveterinária da Região Neotropical: Um guia ilustrado para identificação de espécies, vol. 1. Butantan, São Paulo, p. 223.. The DNA was extracted from ticks as follows: Individual ticks were washed twice with 1mL of ice-cold phosphate buffered saline (PBS; pH 7.2), then re-suspended in 250 μL of PBS in a screw capped 1.5 mL microcentrifuge tube containing 50 mg of acid-washed, 425–600 microns glass beads (Sigma-Aldrich; product # G8772). The tubes were placed on a mini-beadbeater-16 apparatus (Biospec; Bartlesville, USA), and the ticks were disrupted by a single cycle of agitation (60 seconds). Cell lysis was completed by the addition of 250 μL of cell disruption solution (20 mM Tris-HCl, 20 mM EDTA, 400 mM NaCl, 1% sodium dodecyl sulfate, 10 mM CaCl₂) and 20 μL of proteinase K (20 μg/mL⁻¹; Sigma-Aldrich). Lysates were incubated for 3 hours at 56 °C, and DNA was extracted by single rounds of phenol and phenol chloroform treatment, followed by precipitation with an equal volume of isopropanol for 30 min at room temperature. Precipitated (16,000× g) DNA pellets were desalted twice with 70% ethanol and re-suspended overnight at 4 °C in 50 μL of Buffer AE (10 mM Tris-HCl, 0.5 mM EDTA, pH 9.0), and stored at −20 °C.

Individual DNA samples were examined by PCR using the primers CS-239 and CS-1069, which amplify an 834-bp fragment of the gltA gene of all known Rickettsia species and the primers 17k-5 and 17k-3, which amplify a 549-bp fragment of the rickettsial htrA gene (Labruna et al., 2007bLabruna MB, Pacheco RC, Nava S et al. (2007b). Infection by Rickettsia bellii and Candidatus“Rickettsia amblyommii” in Amblyomma neumanni ticks from Argentina. Microb Ecol 54:126–133.). Samples which were positive for these two assays were further tested by additional PCR protocols in order to undertake genetic characterization of the Rickettsia isolates. Additional protocols employed the primers Rr190.70p and Rr190.602n, which amplify a 530-bp fragment of the rickettsial ompA gene (Labruna et al., 2007bLabruna MB, Pacheco RC, Nava S et al. (2007b). Infection by Rickettsia bellii and Candidatus“Rickettsia amblyommii” in Amblyomma neumanni ticks from Argentina. Microb Ecol 54:126–133.), and primers 120-M59 and 120–807, which amplify an 865-bp fragment of the rickettsial ompB gene (Roux and Raoult, 2000).

The PCR mixtures (25 μL) contained 2.5 μL of Platinum Taq DNA polymerase buffer (Life Technologies, Brasil), 2.5 mM MgCl₂, 200 μM dNTPs, 20 pmoles of each primer, 0.5 units of Platinum Taq DNA polymerase, and 2 μL of DNA template. Samples were initially heated to 95 °C for 5 min to denature the template and activate the polymerase, followed by 40 repeated cycles of denaturation at 95 °C for 20 seconds, annealing at 52 °C for 20 seconds, and extension at 72 °C for 30 seconds (htrA and ompA) or for 40 seconds (gltA and ompB), followed by a final extension at 72 °C for five minutes. PCR products were analyzed by gel electrophoresis (1.5% agarose), and the amplicon sizes were determined by comparison with a DNA molecular weight marker (GeneRuler 100 bp DNA Ladder, product # SM024, Thermo Scientific).

Nucleotide sequencing of PCR products was performed as follows: 10 μL of PCR products were treated with Exo-Sap-IT (GE Healthcare), according to the manufacturer’s protocol and sequenced in both directions, employing the amplification primers, using the BigDye Ready Reaction mix (ABI Corp), and reaction products were analyzed on a 3500 automated genetic analyzer (ABI Corp). Sequence alignments were performed using Sequencher (Version 5.2, Genecodes Corporation, CA). Aligned sequences were entered into the BLAST search algorithm (Altschul et al., 1990Altschul SF, Gish W, Miller W et al. (1990) Basic local alignment search tool. J Mol Biol 215:403–410.) and the NCBI nucleotide database to determine gene identity.

Results

A total of 10 adult ticks (8 males, 2 females) from C. subspinosusand nine male ticks from C. insidiosus were obtained (Table 1). DNA was extracted from all the ticks and examined employing PCR assays targeting the rickettsial genes gtlA, encoding citrate synthase and htrA, encoding a 17 kDa outer membrane antigen. Six A. longirostre ticks produced amplicons of the expected molecular weight for both target sequences. Comparative sequence analysis of the htrA amplicon generated from one of the ticks collected from C. insidiosus revealed 100% nucleotide sequence similarity (484 of 484 bases sequenced) with sequences deposited as the htrA sequence of R. bellii (GenBank accession numbers, CP00849 and CP00087). In addition, the gltAamplicon derived from the same tick showed 99.9% nucleotide sequence similarity (790/791 nucleotides), with sequences deposited as the gltA gene of R. bellii (GenBank accession numbers, CP00849 and CP00087). As such, the tick was considered to be infected with R. belli and represented the first recorded detection of this species in A. longirostre. The novel R. bellii sequences were deposited in the GenBank with the accession numbers KJ534308 (htrA) and KJ534309 (gltA).

Sequencing of the htrA, gltA, ompA, and ompB amplicons obtained from the five other PCR positive ticks (four collected from C. subspinosusand one from C. insidiosus) revealed them to be identical to each other and showed similarity levels of 99.4% (477/480 for htrA), 100% (788/788 for gltA), 99.6% (485/487 for ompA), and 99.4% (812/817 for ompB) to the corresponding sequences of R. amblyommii strain Aranha (GenBank accession numbers, AY360215, AY360216, AY360213, and AY360214, respectively). The novel sequences were deposited in the GenBank with the following accession numbers KJ534311 (htrA), KJ534310 (gltA), KJ534312 (ompA), and KJ534313 (ompB).

Discussion

The lack of amplification of ompB and ompA from the DNA extracted from one of the ticks collected from C. insidiosussuggested the presence of a non-spotted fever group (SFG) rickettsial agent. Subsequent sequence analysis confirmed the suspicion and identified the bacterium as R. bellii. This is the first report of R. bellii infecting adults of A. longirostre and the first report of this species of Rickettsia in the state of Bahia. R. bellii represents a rickettsial agent of undetermined pathogenicity (Labruna et al., 2009Labruna MB (2009) Ecology of Rickettsia in South America. Ann N Y Acad Scien 1166:156–166.; Labruna et al., 2011Labruna B, Mattar S, Nava S et al. (2011) Rickettsioses in Latin America, Caribbean, Spain and Portugal, Rev Med Vet Zootec Córd 16:2435–2457.), which has been detected in a variety of tick species throughout the New World (Labruna et al., 2004aLabruna MB, Whitworth T, Bouyer DH et al. (2004a) Rickettsia bellii and Rickettsia amblyommii in Amblyomma ticks from the state of Rondônia, Western Amazon, Brazil. J Med Entomol 41:1073–1081.; Labruna et al., 2007aLabruna MB, Wlippo LFS, Demetrio C et al. (2007a). Ticks collected on birds in the state of São Paulo, Brazil. Exp Appl Acarol 43:147–160.; Pacheco et al., 2008Pacheco RC, Rosa S, Richtzenhain L et al. (2008) Isolation of Rickettsia bellii from Amblyomma ovale and Amblyomma incisum ticks from Southern Brazil. Rev MVZ Córdoba 13:1273–1279.; Barbieri et al., 2012Barbieri ARM, Romero L, Labruna MB (2012) Rickettsia bellii infecting Amblyomma sabanerae ticks in El Salvador. Pathog Glob Heal 106:188–189.). In the specific case of Brazil, Labruna et al. (2004a)Labruna MB, Whitworth T, Bouyer DH et al. (2004a) Rickettsia bellii and Rickettsia amblyommii in Amblyomma ticks from the state of Rondônia, Western Amazon, Brazil. J Med Entomol 41:1073–1081. reported R. bellii as the species most frequently encountered in Amblyomma ticks collected from eight areas of the Amazon forest, and Pacheco et al.(2009)Pacheco RC, Horta MC, Pinter A et al. (2009) Pesquisa de Rickettsia spp em carrapatos Amblyomma cajennense e Amblyomma dubitatum no Estado de São Paulo. Rev Soc Bras Med Trop 42:351–353. related the presence of R. bellii in 634 (23.8%) of 2,666 A. dubitatum ticks examined, in the state of São Paulo, Brazil. To date, Ixodes loricatus, Haemaphysalis juxtakochi, and 13 species of the genus Amblyomma (A. ovale, A. oblongoguttatum, A. scalpturatum, A. humerale, A. rotundatum, A. aureolatum, A. dubitatum, A. incisum, A. nodosum, A. varium, A. neumanni, A. tigrinum, and A. sabanerae (Barbieri et al., 2012Barbieri ARM, Romero L, Labruna MB (2012) Rickettsia bellii infecting Amblyomma sabanerae ticks in El Salvador. Pathog Glob Heal 106:188–189.; Labruna et al., 2011Labruna B, Mattar S, Nava S et al. (2011) Rickettsioses in Latin America, Caribbean, Spain and Portugal, Rev Med Vet Zootec Córd 16:2435–2457.; Ogrzewalska et al., 2012aOgrzewalska M, Literak I, Cardenas-Callirgos JM et al. (2012a) Rickettsia bellii in ticks Amblyomma varium Koch, 1844, from birds in Peru. Tick Tick Born Dis 3:254–256.), have been found to be infected with R. belli in Latin America. The elevated occurrence of infection observed in Amblyomma ticks with this rickettsial agent, has led some authors to suggest the existence of a symbiotic co-evolution of these species (Labruna et al., 2004aLabruna MB, Whitworth T, Bouyer DH et al. (2004a) Rickettsia bellii and Rickettsia amblyommii in Amblyomma ticks from the state of Rondônia, Western Amazon, Brazil. J Med Entomol 41:1073–1081.).

Nucleotide sequencing of the PCR products generated from the five additional A. longirostre demonstrated that all of them were infected with a genetic variant of R. amblyommii, which showed an elevated level of nucleotide similarity (99.4% to 100%) to sequences originating from R. amblyommii strain Aranha. These findings extend the geographic distribution of this species of Rickettsia to southern Bahia, and provide additional evidence for the role of adult A. longirostre as a source of this bacterium. In this context, the strain Aranha was originally identified in DNA pooled from two A. longirostre adult male ticks recovered from the arboreal Brazilian porcupine, C. prehensilis, in the Amazonian state of Rondonia (Labruna et al., 2004bLabruna MB, Mcbride JW, Bouyer DH et al. (2004b) Molecular evidence for a spotted fever group Rickettsia species in the tick Amblyomma longirostre in Brazil. J Med Entomol 41:533–537.).

The bacterium R. amblyommii is a SFG rickettsial agent with a broad distribution throughout the Americas (Labruna et al., 2011Labruna B, Mattar S, Nava S et al. (2011) Rickettsioses in Latin America, Caribbean, Spain and Portugal, Rev Med Vet Zootec Córd 16:2435–2457.), having been initially recorded in the lone star tick, Amblyomma americanum from the USA (Burgdorfer et al., 1981Burgdorfer W, Hayes SF, Thomas L et al. (1981) A new spotted fever group rickettsia from the lone star tick. In: R.W. Anacker (ed) Rickettsiae and Rickettsial Diseases. Academic Press, New York, p. 213–267.). Recent data (Zhang et al., 2012Zhang X, Ren X, Norris DE et al. (2012) Distribution and infection frequency of Candidatus Rickettsia amblyommii in Maryland populations of the lone star tick Amblyomma americanum) and culture in an Anopheles gambiae mosquito cell line. Ticks Tick Born Dis 3:38–42.) revealed that R. amblyommii infection occured in 40–60% of A. americanum collected in the USA. In the case of Brazil, five species of the genus Amblyomma i.e., A. cajennense, A. coelebs, A. longirostre, A. geayi (Labruna et al., 2011Labruna B, Mattar S, Nava S et al. (2011) Rickettsioses in Latin America, Caribbean, Spain and Portugal, Rev Med Vet Zootec Córd 16:2435–2457.), and A. auricularium (Saraiva et al., 2013Saraiva DG, Nieri-Bastos FA, Horta MC et al. (2013) Rickettsia amblyommii Infecting Amblyomma auricularium Ticks in Pernambuco, Northeastern Brazil: Isolation, Transovarial Transmission, and Transstadial Perpetuation. Vector-Borne and Zoo Dis 13:615–618.), have been identified as being infected with this bacterium.

Despite being classified as a SFG agent, R. amblyommii is generally considered to be of undetermined pathogenicity, with some authors considering it to be non-pathogenic (Burgdorfer et al., 1981Burgdorfer W, Hayes SF, Thomas L et al. (1981) A new spotted fever group rickettsia from the lone star tick. In: R.W. Anacker (ed) Rickettsiae and Rickettsial Diseases. Academic Press, New York, p. 213–267.; Parola et al., 2013Parola P, Paddock CD, Socolovschi C et al. (2013) Update on tick-borne rickettsioses around the world: a geographic approach. Clin Microbiol Rev 26:657–702.; Saraiva et al., 2013Saraiva DG, Nieri-Bastos FA, Horta MC et al. (2013) Rickettsia amblyommii Infecting Amblyomma auricularium Ticks in Pernambuco, Northeastern Brazil: Isolation, Transovarial Transmission, and Transstadial Perpetuation. Vector-Borne and Zoo Dis 13:615–618.). Nevertheless, it is pertinent to note that possible human infections with this agent have been reported in the USA (Apperson et al., 2008Apperson CS, Engber B, Nicholson WL et al. (2008) Tick-borne diseases in North Carolina: is “Rickettsia amblyommii” a possible cause of rickettsiosis reported as Rocky Mountain spotted fever? Vect Bor Zoonotic Dis 5:597–606.). Further support for a potential role of this bacterium in human disease was provided by the findings of Jiang et al.(2010)Jiang J, Tamasin Y, Melissa KM et al. (2010) Stromdahl, and Allen L. Richards. Vector- Born Zoonotic Dis 10:329–340., which demonstrated, via quantitative real-time PCR, that R. amblyommii was present in 80.5% (58 of 72) of pools of lone star ticks and in 66.5% (244 of 367) of individual A. americanumticks recovered from humans in the USA during the period 2002 to 2005. Data from serological surveillance of dogs in the Pantanal region of Brazil provided evidence for infection by R. amblyommii most likely via the tick A. cajenennse (Melo et al., 2011Melo ALT, Martins TF, Horta MC et al. (2011) Seroprevalence and risk factors to Ehrlichia spp. and Rickettsia spp. in dogs from the Pantanal Region of Mato Grosso State, Brazil. Ticks Tick Born Dis 2:213–218.). Moreover, a subsequent study of birds and other wild animals from the Atlantic Forest in the state of São Paulo, Brazil (Ogrzewalska et al., 2012bOgrzewalska M, Saraiva DG, Moraes-Filho J et al.(2012b) Epidemiology of Brazilian spotted fever in the Atlantic Forest, state of São Paulo, Brazil. Parasitol 139:1283–300.) also recorded high levels of sero-conversion for R. amblyommii in small mammals and detected R. amblyommii by PCR in 41.7% of A. longirostre ticks collected from birds. Such data clearly demonstrate that this species of Rickettsia is widely distributed and is circulating within wild and domestic animal populations in Brazil. Studies carried out by Saraiva et al.(2013)Saraiva DG, Nieri-Bastos FA, Horta MC et al. (2013) Rickettsia amblyommii Infecting Amblyomma auricularium Ticks in Pernambuco, Northeastern Brazil: Isolation, Transovarial Transmission, and Transstadial Perpetuation. Vector-Borne and Zoo Dis 13:615–618. showed that R. amblyommii can be perpetuated transstadially and transmitted transovarially in A. auriculariumticks, and that such behavior is important for the maintenance of R. amblyommii in nature.

Studies of rickettsial infections in Brazilian ticks in forest environments have traditionally focused on terrestrial hosts, e.g., capybaras, anteaters, and horses, and more recently on wild birds (Ogrzewalska et al., 2012bOgrzewalska M, Saraiva DG, Moraes-Filho J et al.(2012b) Epidemiology of Brazilian spotted fever in the Atlantic Forest, state of São Paulo, Brazil. Parasitol 139:1283–300.). In contrast, arboreal mammals have received limited attention as hosts for ticks, and even less is known regarding their role as reservoirs for tick borne pathogens. This dearth of information most likely reflects the difficulties associated with the capture of these animals. The predominance of R. amblyommii, the species of Rickettsia most frequently detected in immature forms of A. longirostre ticks associated with Brazilian wild birds, provides evidence of a role for porcupines in the maintenance of rickettsial infections within populations of A. longirostre. Clearly, further studies are warranted to fully elucidate the function of these hosts in the ecology of A. longirostre and the rickettsia species present therein.

Acknowledgments

We thank the Rio de Janeiro Research Foundation (Fundação Carlos Chagas Filho de Amparo à Pesquisa do Estado do Rio de Janeiro - FAPERJ) for financial support (process E-26/112.563/2012).

References

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