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Communication 

Biosci. J., Uberlândia, v. 31, n. 5, p. 1496-1500, Sept./Oct. 2015 

MICROORGANISMS CONTAMINATING TICKS COLLECTED AT 
NATURAL RESERVES OR WILD ANIMALS 

 
MICRORGANISMOS CONTAMINANTES DE CARRAPATOS COLETADOS EM 

RESERVAS NATURAIS OU ANIMAIS SELVAGENS 
 

Jamile de Oliveira PASCOAL1; Maria Marlene MARTINS2; Cristiane Silveira de BRITO3; 
Matias Pablo Juan SZABÓ4 

1. Veterinary Science PhD student at the Federal University of Uberlândia, MG, Brazil. jamileopascoal@yahoo.com.br; 2. Applied 
Immunology and Parasitology PhD student at the Federal University of Uberlândia, MG, Brazil; 3. Biology laboratory technician with a 

PhD in Applied Microbiology, Immunology and Parasitology. Microbiology Teaching and Research Laboratory from the Federal 
University of Uberlândia, Uberlândia, MG, Brazil; 4. Associate Professor at the Federal University of Uberlândia. Ixodology Laboratory 

from the Federal University of Uberlândia, Uberlândia, MG, Brazil.  
 

ABSTRACT: This work investigated microorganisms responsible for the contamination and death of ticks from 
natural reserves and wild animals and later kept in the Laboratory of Ixodology in the Veterinary School of the Federal 
University of Uberlândia. Such investigation aimed prevention of tick death in the laboratory but also search for 
microorganisms to be used in the biological control of ticks. From four tick samples of Amblyomma genus, the following 
agents were isolated: Staphylococus sp, Gram positive bacillus, filamentous fungi of the genera Aspergillus and 
Penicillium, and a yeast identified as Non-albicans Candida and Cryptococcus sp. Even though the source of 
contamination of these ticks is uncertain, this study displayed the necessity of to better evaluating the spread of pathogens 
by ticks, as well as those known to be transmitted solely during tick feeding. 

 
KEYWORDS: Bacteria. Fungi. Contamination. Ixodidae. 

 
INTRODUCTION 

 
Ticks are of great relevance to both public 

and animal health. These parasites are the main 
vectors of pathogens to domestic animals and are 
second to mosquitoes in the case of human beings. 
Besides pathogen transmission, ticks reduce animal 
production and impacts on animal health by 
spoliation, skin lesions, and toxicosis (JONGEJAN; 
UILENBERG, 2004). 

Most of the existing information in Brazil is 
related to ticks from domestic animals whereas a 
huge knowledge gap occurs in the case of ticks 
from wild animals. Nonetheless, these arthropods 
parasitize all terrestrial vertebrates, including birds 
(SONENSHINE, 2002). In fact, ticks rely on their 
hosts for mobility. Under this setting, bird ticks 
might pose a serious threat of disease dissemination 
if vectors of pathogenic microorganisms (ARZUA 
et al., 2003). 

Research of tick-associated microorganisms 
fulfills two objectives; detection of infectious agents 
to human and various animal species as well as 
those pathogenic to the vector and that might be 
used for biological control. Biological control of 
tick vectors is an alternative to currently used 
acaricides that pollute and their efficacy is 
decreasing with the selection of resistant parasite 
populations (SAMISH et al., 2004). Actually, 
several fungi such as Metarhizium anisopliae and 

Beauveria bassiana are pathogenic to ticks. These 
microorganisms massively colonize tick tissues 
killing them in a few days (BITTENCOURT et al., 
1999; GARCIA et al., 2004).  

In nature, microorganisms participate of tick 
control in the environment during the long off-host 
periods (SZABÓ et al., 2009). For this reason it is 
possible to suppose that a few of these 
microorganisms could be used as new biological 
control agents against ticks. The aim of this study 
was to identify microorganisms that allegedly 
colonized and killed ticks in laboratory after capture 
in reserves or picked from wild animals. This 
investigation was necessary to understand high 
mortality rate of ticks in laboratory and to search for 
microorganisms that could be used for biological 
control of these arthropods and detection of 
infectious agents to human and various animal 
species. 

 
CONTENT 

 
All ticks from this study belonged to 

Amblyomma genus and originated from wildlife. 
They were taken to the Ixodology Laboratory of the 
Federal University of Uberlândia and died while 
maintained in an incubator (ELETROLAB®) in 
2008 (Table 1). All ticks were held for at least 15 
days in an incubator at 27 0C, and 80% RH  under 
24h darkness before examining for microorganisms.   

Received: 21/05/14 
Accepted: 20/01/15 



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Biosci. J., Uberlândia, v. 31, n. 5, p. 1496-1500, Sept./Oct. 2015 

Cultures of tick microorganisms were 
prepared as described before (KONEMAN et al., 
2001). Four tick samples (Table 1) covered by 
fungus were placed in one glass tube each with 
saline solution and kept under refrigeration.  Later 
tubes underwent vortexing and each sample was 
placed in two different culture mediums for growth 
of microorganisms according to the manufacturer’s 
instructions. Samples in Sabouraud Dextrose Agar 
(NEOGEN ®), used for fungus growth, were kept in 
room temperature for eight days and samples in 
Agar TSA (Tryptic Soy Agar - BD Difco™), 
used as nutrient source for microorganisms were 
incubated at 37ºC for 48h.  Slide culture was also 
used for identification of fungus. 

Microorganism colonies were identified 
according to morphological and staining 
characteristics (Gram stain) and classic 
microbiologic techniques.  Staphylococcus, genus, 

Gram- positive bacilli and yeast-form fungi were 
characterized by morphology. Yeast-form fungi 
were identified for microscopic features such as 
germinative tube and CHROMAGAR Candida was 
used for presumptive characterization of Candida 
albicans, Candida tropicalis and Candida krusei. 
Urease production test was used to distinguish 
Cryptococcus sp. from Candida sp. (KONEMAN et 
al., 2001).  

Staphylococcus sp. and Gram positive 
bacilli colonies grew in the TSA medium and in one 
of the samples an urease positive yeast, 
Cryptococcus sp., grew as well. Aspergillus sp. 
Penicillium sp. grew in Sabouraud medium. Yeast 
found in two plaques was urease negative 
(Candida). CHROMAGAR culture allowed this 
yeast to be classified as Non-albicans Candida 
(Table 1). 

 
Table 1. Origin of parasites and contaminant microorganisms of ticks from reserves or wild animals, 

Uberlândia, MG. 
 
Sample Ticks  Origin Contaminant 

Microorganisms 
1 2 nymphs 

Amblyomma sp. 
Larvae captured in Glória Farm of the 
Federal University of Uberlândia and 
fed on chick. 

Aspergillus sp. 
Penicillium sp. 
Non-albicans Candida 
Gram-positive bacilli  
 

2 6 nymphs 
Amblyomma sp. 

Cerrado (savannah) from the Clube 
Caça e Pesca reserve, Uberlândia, MG. 

Aspergillus sp. 
Staphylococcus sp. 
 
 

3 Nymph 
Amblyomma sp. 

Giant anteater found within the city of 
Frutal, MG. 

Aspergillus sp. 
Cryptococcus sp. 
Gram-positive bacilli 
 

4 Nymph 
Amblyomma sp. 

Nymph of Bird captured at the Glória 
Farm from the Federal University of 
Uberlândia and fed on chick. 

Aspergillus sp. 
Penicillium sp. 
Non-albicans Candida 
Staphylococcus sp. 

 
 

                                         
Figure 1. Microorganisms identified in TSA medium.                Figure 2. Microorganisms identified in Sabouraud medium.                                  

By this time, it is impossible to determine origin of 
microorganisms on ticks since this vectors had a 

long way from nature until microorganism isolation 
and identification. It is worthwhile mentioning that 



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Biosci. J., Uberlândia, v. 31, n. 5, p. 1496-1500, Sept./Oct. 2015 

ticks from domestic animals were kept in the same 
incubator but only those from wildlife were covered 
by fungus. This indicates that origin of the fungus 
was not the incubator (routinely cleaned). It is also 
impossible to know if ticks died because of the 
infection with the detected microorganisms. 
However, the knowledge of the association of these 
microorganisms with ticks is, on its own, a relevant 
observation; it indicates that ticks can carry 
pathogens, at least mechanically.  A second 
interesting observation relates a possible role in 
nature by microorganism diversity on ticks. Even 
though some of them can infect and kill these 
vectors, others might be related to the inhibition of 
pathogenic ones. Such situation seems to have 
occurred in experiments with Amblyomma incisum 
(SZABÓ et al., 2009). These authors observed that 
if maintained in incubators at highly humid 
conditions, similar to the ones found in their natural 
settings, engorged female ticks were soon fungus 
covered and died without ovipositing. However, 
female ticks from the same cohort kept in metal 
cages in humid forests, oviposited normally.  
Several influences should be considered in this case, 
but it can be speculated that fungus infection was 
controlled by microbiota from the forest.  

Bacteria found in this work were all Gram-
positive and ubiquitous in nature. They are found on 
the soil, air, water or as commensals on animal and 
human skin. These bacteria have both pathogenic 
and no-pathogenic strains and infection and 
transmission vary according to the strain (CARTER, 
1988; SONGER & POST, 2005). 

Aspergillus genus was the most prevalent 
among the isolated yeast-form fungi, followed by 
Penicillium, both saprophytic. In a similar work, 
Monteiro et al. (2003), found mainly Penicillium 
followed by Aspergillus, and four other yeast-form 
fungi on ticks undergoing natural infection. These 
authors highlighted that medium used for culture as 
well as competition among fungus may have 
inhibited growth of entomopathogenic fungus, as 
they grow slower than those saprophytic. Such 
might have happened in our work as well.  

According to Passoni (1999), Cryptococcus 
spp. can be found in the soil, decomposing wood 
and bird excreta, especially of pigeons. Pigeons are 
mechanic vectors and their excreta is a natural 
substrate for the fungus. These birds by braking and 
scraping wood for nests seems to create ideal 
conditions for the survival of the pathogenic 
Cryptococcus neoformans.  

Pascoal et al. (2013) observed on survey for 
ticks on birds that Amblyomma nodosum was a 

major tick species on passerine birds at a Cerrado 
reserve. While nymphs parasitize birds, adults of 
this tick species are routinely found on anteaters 
(Myrmecophaga tridactyla, Tamandua 
tetradactyla) (MARTINS et al., 2004). In this 
context, a few bird species pose a potential problem 
for tick-associated pathogen dissemination thanks 
to their high capacity of moving. An especial 
attention should be given to sinantropic birds such 
as pigeons, sparrows and others. In the case of the 
Cryptococcus sp. recovered from an A. nodosum 
from an anteater, fungus could have infected tick in 
nature (Cerrado). On the other way round, infection 
could have occurred in the Veterinary Hospital 
where the anteater remained for a few days close to 
several other animals from various origins.  

Most of the observations about 
microorganisms pathogenic to ticks are restricted to 
entomopathogenic fungus such as Metarhizium 
anisopliae and Beauveria bassiana (GARCIA et al., 
2008; BITTENCOURT et al., 1999; PRETTE et al., 
2005). Much less is known about other fungus 
species on ticks, particularly of the Amblyomma 
genus.  

Agents such as Aspergillus, Candida, 
Cryptococcus and zygomicet species were once 
considered laboratory contaminants and clinically 
irrelevant. These species, however, are by now 
recognized as pathogens associated to ailments 
such as endocarditis, lung infections, keratitis and 
others, particularly in immunosuppressed patients 
(ANVISA, 2004). 

Thus bacterial (Staphylococcus sp. and 
Gram- positive) and fungi and yeast (Aspergillus 
sp., Penicillium sp., Candida sp. e Cryptococcus 
sp.) found herein, irrespective of contamination 
source, whether in nature or later  in human settings 
(veterinary hospital, laboratory), displays the 
capacity of ticks disseminating pathogens not only 
during hematophagy but also of those carried on tick 
surface.  

 
ACKNOWLEDGEMENTS 

 
We are indebted to Dr. Paulo Gontijo Pinto 

Filho, head of the Microbiology Teaching and 
Research Laboratory from the Federal University of 
Uberlândia, for permission to use the Laboratory 
and collaborating with material. This research was 
supported by Conselho Nacional de 
Desenvolvimento Científico e Tecnológico – CNPq 
(scholarship to J.O., Pascoal and Academic Career 
Research Fellowship to M.P.J. Szabó). 

 
 



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Biosci. J., Uberlândia, v. 31, n. 5, p. 1496-1500, Sept./Oct. 2015 

 
RESUMO: Neste trabalho foram investigados microrganismos responsáveis pela colonização e morte de 

carrapatos provenientes de reservas naturais ou animais selvagens e mantidos posteriormente no Laboratório de 
Ixodologia da Faculdade de Medicina Veterinária da Universidade Federal de Uberlândia. Esta investigação se fez 
necessária para tentar prevenir mortalidade de carrapatos no laboratório, mas também para contribuir com a busca por 
microrganismos que poderiam ser utilizados no controle biológico do ácaro. Foram isolados de cinco amostras de 
carrapatos do gênero Amblyomma os seguintes microrganismos: Staphylococus sp, bacilos Gram positivos, fungos 
filamentosos dos gêneros Aspergillus e Penicillium, além de leveduras identificadas como Candida não-albicans e 
Cryptococcus sp. Mesmo que a origem da contaminação dos carrapatos com estes microrganismos seja incerta este 
trabalho indica a necessidade de se avaliar melhor a difusão de outros patógenos por carrapatos, além daqueles 
transmitidos com a hematofagia. 

 
PALAVRAS-CHAVE: Bactérias. Fungos. Contaminação. Ixodídeos. 

 
 
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