Bats used as hosts by Amblyomma sculptum (Acari: Ixodidae) in Northeastern Brazil and its implications on tick-borne diseasesABSTRACT
Amblyomma Koch, 1844 is distributed worldwide, with ca. 130 species currently recognized. These ticks are vectors of pathogens to animals and humans, including the causative agent of the New World Rocky Mountain spotted fever. Species of the Amblyomma parasitize a wide range of organisms, especially medium and large terrestrial mammals. Here we report for the first time the association of Myotis lavali Moratelli, Peracchi, Dias & Oliveira, 2011, Noctilio albiventris Desmarest, 1818 and Noctilio leporinus (Linnaeus, 1758) as hosts for Amblyomma sculptum Berlese, 1888. The ticks were originally identified as Amblyomma cajennense (Fabricius, 1787), in 2011. However, a later taxonomic review indicated that the species of the A. cajennense complex occurring in the Caatinga is A. sculptum. We also discuss the ecoepidemiological implications of this association.
KEY WORDS: Caatinga; Chiroptera; hard ticks; neotropics; parasitism
Ticks are vectors of pathogens to humans and animals, being of public health importance (Jongejan and Uilenberg 2004). Hard ticks of Amblyomma Koch, 1844 are the main vectors of Rickettsia rickettsii, the causative agent of Rocky Mountain Spotted Fever in humans, and other bacteria that cause anaplasmosis and ehrlichiosis, among others (Sangioni et al. 2005, Schulze et al. 2005, Labruna 2009, Witter et al. 2016).
Amblyomma is one of the most common hard tick genera, with ca. 130 species, of which more than half are endemic to the New World (Guglielmone et al. 2010). Amblyomma sculptum Berlese, 1888, member of the A. cajennense complex, occurs in the central and eastern portions of South America, including northern Argentina, Bolivia, Paraguay, and Brazil (Nava et al. 2014, Martins et al. 2016). Horses and capybaras are the primary hosts for these ticks (Sangioni et al. 2005, Labruna 2009). However, A. sculptum also feeds on many domestic and wild terrestrial mammals (Garcia et al. 2013, Brites-Neto et al. 2015, Martins et al. 2016).
Although there are many studies reporting the association between ectoparasites and bats (e.g., Christe et al. 2003, Dick and Patterson 2006, Franck et al. 2013, Muñoz-Leal et al. 2016), bats rarely have been reported as hosts for the New World Amblyomma species. New findings on host/parasite interactions are crucial for the understanding of evolutionary processes of species diversification and habitat occupation, providing additional insights on the epidemiology of emerging infectious diseases. Herein we describe new records of New World bats parasitized by hard tick A. sculptum.
Between October 2010 and October 2012, we performed thirty nights of bat sampling in São João do Piauí (08°19’43”S; 42°21’17”W, elevation of 270 m), state of Piauí, Northeastern Brazil. The study area comprises remnants of caatinga’s xerophytic vegetation, pastures and agricultural fields for cassava, maize, palm and cashew production. See Novaes et al. (2015) for a detailed description of the study site. Bat samplings were carried out using 10 ground level mist-nests (Zootech®, 9 x 3 m, 30 mm mesh) placed in trails, natural clearings, and along riverbanks. Mist-nets were opened from six hours after dusk (ca. 6:00 pm). Bats were identified in the field, and their associated ectoparasites were collected with tweezers. Collected ticks were identified per morphological characters proposed by Barros-Battesti et al. (2006).
On October 6th, 2010, at the pond margin of an abandoned rural property, we captured an adult male of Myotis lavali Moratelli, Peracchi, Dias & Oliveira, 2011 (Chiroptera: Vespertilionidae) parasitized by a sub-adult of A. sculptum, which was adhered to the face of the bat (Fig. 1). The bat and the tick were collected and deposited in the mammal collection of Museu Nacional (MN 75191). On October 7th, 2010, at the same locality, we captured a pregnant female of Noctilio leporinus (Linnaeus, 1758) (Chiroptera: Noctilionidae) with a sub-adult A. sculptum insider the ear. The tick was removed, and the bat released in same location. On April 2, 2012, at the same locality, we captured one adult female of Noctilio albiventris Desmarest, 1818 parasitized by some sub-adult individuals of A. sculptum, together with several soft ticks Ornithodoros sp. (Acari: Argasidae), on the top of head, and along the dorsum, wings and uropatagium (Fig. 2). The bat and ticks were deposited in the mammal collection of Museu Nacional (MN 79943).
The hard ticks were first identified as Amblyomma cajennense (Fabricius, 1787) in 2011, which was the only New World species recognized at that time. However, subsequent studies split A. cajennense into six species (see Nava et al. 2014, Martins et al. 2016), and based on geographic location, our records correspond to A. sculptum. The other species in the genus in Brazil is A. cajennense, which is restricted to the Amazon basin (Nava et al. 2014).
(1) Individual of Myotis lavali (MN 75191) parasitized by an engorged Amblyomma sculptum in the xerophytic caatinga from Northeastern Brazil. Photo: Carlos Cândido. (2) Individual of Noctilio albiventris (MN 79943) parasitized by some sub-adult individuals of hard tick Amblyomma sculptum and soft tick Ornithodoros sp. in the xerophytic caatinga from Northeastern Brazil. Photo: Roberto Leonan M. Novaes.
These are the first records of A. sculptum using bats as hosts. However, there are other records of Neotropical Myotis and Noctilio being parasitized by other tick species including the congener. Amblyomma triste Koch, 1844, which has been recorded in Myotis albescens (E. Geoffroy, 1806) from Paraguay (Venzal et al. 2003), and Ornithodoros hasei (Schulze, 1935) (Argasidae) recorded from N. leporinus and that was infected with Rickttesia spp. in French Guiana (Tahir et al. 2016).
There are few records of Amblyomma ticks parasitizing bats in the world (e.g., Jones et al. 1972, Barros et al. 1998, Guerra and Serra-Freire 1999, Venzal et al. 2003, Ahamad et al. 2013, Alurralde and Díaz 2019). This might be partially explained by the bat behavior of social grooming (Carter and Leffer 2015), resulting in the removal of large sized ectoparasites. Bats were most frequently found infested by immature stages of soft ticks from family Argasidae (Franck et al. 2013, Munõz-Leal et al. 2016, Tahir et al. 2016), which are consistently smaller than those of the Amblyomma species. Captive observations and experiments could test this hypothesis.
Amblyomma spp. appear to not have host specificity, and the associations between ticks and their hosts seem to be more related to environmental factors than determinants inherent to the species (Nava and Guglielmone 2013). Moreover, the host preference differed between life stages, with immature ticks typi cally being more generalist than their adult conspecifics (Nava and Guglielmone 2013, Espinaze et al. 2015, Esser et al. 2016). As a result, in disturbed habitats without the original faunal composition, ectoparasites may infest different hosts, especially the immature ticks (McCoy et al. 2013, Esser et al. 2019, Kiene et al. 2020). Therefore, we hypothesize that the abandonment of rural property and withdrawal of livestock and domestic animals induced a new parasitic interaction between bats and A. sculptum by forcing the parasite to use different hosts.
The new records here reported extend the host range used by New World hard ticks from genus Amblyomma, which can furnish new insights about Rickettsial transmission cycle. Bats have high vagility when compared with terrestrial animals, performing seasonal migrations of thousands of kilometers and errant movements of hundreds of kilometers (Wiederholt et al. 2013, Arnone et al. 2016). Moreover, bats are reservoirs of Rickttesia spp. (D’Auria et al. 2010, Tahir et al. 2016), which makes them an important component for researches investigating pathogen dispersal and tick-borne diseases outbreaks.
There are several records of bat parasitized by hard ticks of the genus Ixodes, including bat species from Myotis restricted to the Old World (Hassan et al. 2010, Hornok et al. 2014, Burazerović et al. 2015, Frank et al. 2015). These findings reinforce the need to continue investigating relationships between bats and ectoparasites, and their implications in public health.
ACKNOWLEDGEMENTS
We are grateful to Maria Lúcia Guimarães for assistance with tick identification; to Carlos Cândido for assistance in the fieldwork and in the photographic record. RLMN receives a PhD studentship from the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior.
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Publication Notes
Publication Dates
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Publication in this collection
14 Dec 2020 -
Date of issue
2020
History
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Received
22 July 2020 -
Accepted
30 Sept 2020 -
Published
02 Nov 2020
