Acta Herpetologica 12(1): 103-108, 2017

ISSN 1827-9635 (print) © Firenze University Press 
ISSN 1827-9643 (online) www.fupress.com/ah

DOI: 10.13128/Acta_Herpetol-18765

Nematodes infecting Anotosaura vanzolinia (Squamata: 
Gymnophthalmidae) from Caatinga, northeastern Brazil

Bruno Halluan S. Oliveira¹, Adonias A. Martins Teixeira¹,*, Romilda Narciza M. Queiroz¹, João A. Arau-
jo-Filho¹, Diêgo A. Teles¹, Samuel V. Brito2, Daniel O. Mesquita¹
1 Programa de Pós-Graduação em Ciências Biológicas (Zoologia), Departamento de Sistemática e Ecologia – DSE, Centro de Ciências 
Exatas e da Natureza – CCEN, Universidade Federal da Paraíba – UFPB, Cidade Universitária, Campus I, CEP 58059-900, João Pes-
soa, PB, Brazil. *Corresponding author. E-mail: adoniasteixeira01@gmail.com
2 Centro de Ciências Agrárias e Ambientais, Universidade Federal do Maranhão, Boa Vista, CEP 65500-000. Chapadinha, MA, Brazil.

Submitted on 2016, 30th August; revised on 2016, 13th December; accepted on 2016, 21st December 
Editor: Paolo Casale

Abstract. The present study investigated the composition of helminth parasites of the completely unknown lizard 
Anotosaura vanzolinia (Squamata: Gymnophthalmidae) and evaluated the effects of sex, host size, and seasonality 
on endoparasite abundance in two areas of Caatinga, northeast Brazil. We collected 110 lizards between May 2013 
to June 2014 and found 173 nematodes (overall prevalence: 16.3%), with 49 nematodes infecting seven adult males 
(prevalence: 25%), 84 nematodes infecting six adult females (Prevalence: 23%), and 40 nematodes infecting five juve-
niles (prevalence: 8.9%), where one nematode was in the lungs and 172 were in the gastrointestinal tracts. We identi-
fied all nematodes as Oswaldocruzia brasiliensis, representing a new record for the host and for Gymnophthalmidade, 
showing overall intensity of infection ± SD of 9.6 ± 5.2. Furthermore, abundance of endoparasites was related to the 
rainy season and sex, but not to host body size (SVL).

Keywords. Parasites, Lizards, Neotropical, Oswaldocruzia brasiliensis, Nematodes.

In the last decade, there has been an increasing 
number of studies about endoparasites affecting rep-
tiles. The last survey in South America recorded about 
155 helminth species infecting lizards and amphisbae-
nians (Ávila and Silva, 2010). Although the number of 
these studies in Neotropical regions is still increasing, 
some lizard families are more deeply studied, such as 
Leiosauridae (Vrcibradic et al., 2008; Barreto-Lima and 
Anjos, 2014; Dorigo et al., 2014); Phyllodactylidae (Ávi-
la et al., 2010a; Sousa et al., 2010); Teiidae (Brito et al., 
2014b), and Tropiduridae (Almeida et al., 2009; Anjos et 
al., 2012; Pereira et al., 2012). In contrast, studies about 
Gymnophthalmidae are scarce and mainly regard new 
host records (Ávila and Silva, 2010). Currently, parasi-
tological studies are only available for ten Gymnoph-
thalmidae species in Neotropical regions: Cercosaura 

eigenmanni and C. oshaughnessyi (Bursey and Goldberg, 
2004); Alopoglossus angulatus (Goldberg et al., 2007b); 
Leposoma osvaldoi and Neusticurus ecpleopus (Goldberg 
et al., 2007a); Iphisa elegans elegans (Ávila et al., 2010b); 
Bachia scolecoides and Cercosaura ocellata ocellata (Ávila 
and Silva, 2011); and Micrablepharus maximiliani (Brito 
et al., 2014a).

Gymnophthalmid lizards, popularly known as micro-
teiids, are small (40 to 150 mm snout-vent length) and 
commonly distributed in Neotropical regions from South 
Mexico to Argentina, including some islands of Central 
and South America, totalling 220 species in 48 genera 
(Presch, 1980). In Brazil, there are about 93 gymnoph-
thalmid species, distributed in 33 genera. One of them is 
Anotosaura, which comprises two species, A. vanzolinia 
and A. collaris (Costa and Bérnils, 2015).



104 B.H.S. Oliveira et alii

Anotosaura vanzolinia is a small lizard restricted to 
semi-arid regions in northeastern Brazil, locally known 
as Caatinga, with fossorial habits, occurring in sites with 
accumulated leaf litter, its diet is comprised basically of 
microarthropods associated with sites where these lizards 
live (Oliveira and Pessanha, 2013). However, there are no 
reports about parasites of A. vanzolinia, possibly because 
A. vanzolinia is a rare lizard in Caatinga. Therefore, this 
study aims to evaluate the effect of sex, host size, and sea-
sonality on the composition and abundance of helminths 
associated with the lizard Anotosaura vanzolinia, using a 
considerable sample from Caatinga, northeast of Brazil.

We collected Anotosaura vanzolinia specimens dur-
ing expeditions in the Complexo Aluízio Campos For-
est Park (7°16’34”S, 35°53’7”W), a Caatinga area with an 
altitude of approximately 500 m, with shrubby vegeta-
tion represented mainly by Bromeliaceae and Cactaceae, 
a larger number of rock outcrops, and accumulated leaf 
litter (Alves et al., 2010; Silva et al., 2010) and in the São 

José da Mata district (7°11’2.85”S, 35°59’6.17”W), located 
between the arboreal formations locally known as “Bre-
jo” and Caatinga, with an altitude of approximately 700 
m. The site is settled between the “Agreste” and “Sertão”, 
being probably one of the last remains of the transitional 
arboreal vegetation of Paraiba, with typical plant species 
from Caatinga and the Atlantic Forest (Barbosa et al., 
2007). Both sites are located in Paraiba, northeastern Bra-
zil (Fig. 1). Climate is tropical, with a mean temperature 
of 22.9ºC; highest precipitation occurs between March 
and August (99 mm) and lowest between September and 
February (29 mm) (Climate-Date, 2016).

We collected 110 lizards between May 2013 to June 
2014 (Table 1) by hand and using pitfall-traps (six sets 
in each area), constructed with four buckets (20 L each), 
totalling 24 buckets per area, arranged in three lines of 
three meters each, forming angles of 120° from a same 
central point and connected by a plastic fence fixed with 
staples on wooden stakes.

Fig. 1. Collecting sites in Paraíba State (A) in Northeast Brazil, Campina Grande municipality (B). Study areas (C): São José da Mata district 
(SJM) and Complexo Aluízio Campos Forest Park (CAC).



105Nematodes infecting the lizard A. vanzolinia from Brazil

We killed the lizards with a lethal injection of 2% 
lidocaine hydrochloridec and measured snout-vent length 
(SVL) with digital calipers. Subsequently, we sexed them, 
preserved them in 10% formalin, and stored them in 70% 
alcohol. All lizards were kept in the Coleção Herpetológi-
ca da Universidade Federal da Paraíba (CHUFPB). In the 
laboratory, we removed the respiratory and gastrointes-
tinal tracts and analyzed them in a stereomicroscope to 
search for endoparasites. The endoparasites found were 
cleared with Hoyer’s solution, counted, identified, stored 
in 70% alcohol, and kept in the Coleção de Invertebrados 
Paulo Young, in Universidade Federal da Paraíba (UFPB-
NEM: 0001; 0002).

The following infection rates were calculated accord-
ing to Bush et al.(1997), where parasite abundance is 
defined as the total number of parasites found in a sam-
ple (individual host, host population and / or host com-
munity); mean intensity of infection is the total number 
of parasites found in a sample, divided by the number of 
hosts infected with that parasite; prevalence (P%) is the 
number of host infected with one or more individuals of 
a particular parasite species divided by total host number.
Throughout the text, means appear ± 1 SD.

To analyze the influence of SVL on endopara-
site abundance, we performed simple linear regression 
(excluding juveniles), using the Statistica Software, ver-
sion 8.0 (Statsoft, 2007). In addition, we performed a 
generalized linear model (GLM), adopting Poisson’s dis-
tribution, using the Software R, package “R commander” 
(R core team, 2008) to evaluate whether parasite abun-

dance was influenced by host sex, seasonality and inter-
action between sex and seasonality.

We examined 110 Anotosaura vanzolinia speci-
mens, of which 26 were adult females (SVL: 42.6 ± 2.3), 
28 adult males (SVL: 37.9 ± 2), and 56 juveniles (SVL: 
26.7 ± 5.2). We found 173 nematodes (overall preva-
lence: 16.3%), with 49 nematodes infecting seven adult 
males (prevalence: 25%), 84 nematodes infecting six adult 
females (prevalence: 23%), and 40 nematodes infect-
ing five juveniles (Prevalence: 8.9%), where one nema-
tode was in the lungs and 172 were in the gastrointesti-
nal tracts. We identified all nematodes as Oswaldocruzia 
brasiliensis, representing a new host record and the first 
record for Gymnophthalmidade, showing overall inten-
sity of infection of 9.6 ± 5.2 (Table 2).

Simple linear regression revealed a non-significant 
relationship between SVL and endoparasite abundance 
(F1,12 = 4.24; R2 = 0.26; P = 0.061). We observed a sig-
nificant variation between the abundance of endopara-
sites and sex of the host (GL = 3; Z value = - 2.669; P 
= 0.0076), where females had more parasites than males 
(Fig. 2). In addition, abundance of endoparasites was 
higher in the rainy season (GL = 3; Z value = -4. 318; P 
<0.0001) (Fig. 2). However, abundance of endoparasites 
was not influenced by interaction sex-season (GL= 4; Z 
value = 0.024; P = 0.981) (Fig. 2).

Several factors can influence parasitism by helminths 
in reptiles (Aho, 1990), especially host size (Poulin and 
George‐Nascimento, 2007), sex (Galdino et al., 2014), 
season (Brito et al., 2014), and life cycle of the parasite 
(Araujo-Filho et al., 2016). Usually, larger hosts (mass 
and body size) have the capacity to provide shelter to a 
greater number of parasites, consequently, more resources 
for parasite development and reproduction (George‐Nas-
cimento et al., 2004). However, in the present study, we 
did not observe a significant relation between SVL and 
parasite abundance in A. vanzolinia. For lizards, this 
hypothesis is supported mainly by Tropiduridade: Tropi-

Table 1. Number of lizards collected in each sampled area, months 
of the year and season. CAC = Complexo Aluízio Campos Forest 
Park; SJM = São José da Mata District.

Months

Locality

CAC SJM

Wet season Dry season Wet season Dry season

May 8 – 1 –
Jun 9 – 1 –
Jul 4 – 0 –
Aug 8 – 2 –
Sep – 7 –  2
Oct – 9 – 6
Nov – 4 – 2
Dec – 7 – 1
Jan – 16 – 1
Feb – 7 – 1
Mar 6 – 0 –
Apr 7 – 1 –

Table 2. Parasitological data from population of Anotosaura van-
zolinia from Caatinga, Northeast Brazil, infected by Oswaldocruzia 
brasiliensis. P% = prevalence; SD = standard deviation; I = intestine, 
L = lung.

Host 
sex and 
maturity

Host 
sample 

size

SVL/SD 
(mm)

P% (Host 
infected)

Mean 
intensity of 
infection/

SD

Site 
infection

Males 28 37.9 ± 2 25 (7) 7 ± 3.8 I
Females 26 42.6 ± 2.3 23 (6) 14 ± 8.5 I,L
Juveniles 56 26.7 ± 5.2 8.9 (5) 8 ± 3.4 I
Total 110 - 16.3 (18) 9.6 ± 5.2 -



106 B.H.S. Oliveira et alii

durus torquatus (range of intensity: 22.1 ± 20.2) (Ribas et 
al., 1998); T. hispidus (range of intensity: 8.5 ± 1) (Anjos 
et al., 2012); T. torquatus (range of intensity: 8.2 ± 6.9) 
(Pereira et al., 2012); and Teiidae species: Ameiva ameiva 
(range of intensity: 7.2 ± 7.3) (Ribas et al., 1998); A. fes-
tiva (intensity of infestation: 21, range: 1-115) (Ramírez-
Morales et al., 2012). Nevertheless, besides body size and 
host mass, other factors can explain the variation in para-
site abundance, such as ecology (Aho, 1990), physiology 
(Poulin and Mouillot, 2004; Poulin, 2007), behaviour, and 
phylogeny (Poulin and Mouillot, 2005; Patterson et al., 
2008; Brito et al., 2014a).

Furthermore, the small size of A. vanzolinia (SVL = 42 
mm) can constrain the diversification of its parasitic fauna, 
hindering niche differentiation and microhabitat segrega-
tion by endoparasite competitors (Kuris et al., 1980; Ávila 
et al., 2010a) thus explaining the presence of only a single 

nematode species infecting the host studied. This observa-
tion was also recorded in other small lizard species, such 
as Liolaemus lutzae (SVL = 61 mm), Aspronema dorsivit-
tatum (SVL = 64 mm), and Phyllopezus lutzae (SVL = 
42 mm), which exhibit up to two endoparasites species 
(Rocha, 1995; Rocha et al., 2003; Ávila et al., 2010a).

We found significant differences in the abundance 
of nematodes in relation to host sex, where females were 
more parasitized than males. According to Poulin (1996), 
physiological, morphological, and behavioral differences 
between males and females may explain the differences of 
infection rates between sexes. However, due to the absence 
of research that verified possible differences in the ecology 
between the sexes for the lizard A. vanzolinia, we can not 
explain what factors may have influenced the increase of 
the parasite abundance in females in the present study.

The nematode Oswaldocruzia brasiliensis has a mon-
oxenous life cycle (Lent and Freitas, 1935), and congeneric 
species infect mainly frogs (Well Slimane and Durette-
Desset, 1996), lizards (Bursey et al., 2006), and snakes 
(Durette-Desset et al., 2006). According to Anderson 
(2000), monoxenous nematodes can easily be influenced 
by variations in temperature and humidity. Our results 
support this hypothesis, considering that A. vanzolinia 
presents a greater endoparasite abundance in the rainy 
season, mainly because of its fossorial habits, increas-
ing the possibility of infection by O. brasiliensis through 
accidental ingestion of eggs (in the faeces of other hosts, 
substrate in general) or by active penetration of infective 
larvae (via the skin and / or mucosa).This can also explain 
the higher parasite abundance in females, because they lay 
eggs during the rainy season and in humid microhabitats 
to avoid egg desiccation (Oliveira and Pessanha, 2013).

The present study revealed that the parasitic fauna 
of A. vanzolinia from Caatinga consists of a single nem-
atode, Oswaldocruzia brasiliensis, representing the first 
record of infection to the host and to Gymnophthalmi-
dae. Furthermore, endoparasite abundance is related to 
the rainy season and sex, but is not correlated with host 
body size (SVL). 

ACKNOWLEDGMENTS

We thank the Fundação Universitária de Apoio ao 
Ensino, à Pesquisa e à Extensão (FURNE) for provid-
ing collecting permits at Complexo Aluízio Campos, 
Mr. Guilherme Leão, who not only granted access to his 
property in São José da Mata, but also encouraged our 
survey, and Mr. Vandeberg Ferreira Lima for helping with 
statistical analyses. AAMT thank Coordenação de Aper-
feiçoamento da Pessoa de Nível Superior – CAPES for 

Fig. 2. Mean abundance of nematodes between seasons for species 
of lizard A. vanzolinia, males (triangle) and female (circle).



107Nematodes infecting the lizard A. vanzolinia from Brazil

a research fellowship. DAT, JAAF and DOM thank the 
Conselho Nacional de Desenvolvimento Científico e Tec-
nológico – CNPq for a research fellowship (303610/2014-
0).The study was approved by the Instituto Chico Mendes 
de Conservação da Biodiversidade with the permit to 
collect the animals (process 36166-2). We thank Proof-
Reading-Service.com Ltda, for revision professional of 
English version of the manuscript.

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	Acta Herpetologica
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	Joaquín Villamil1,*, Arley Camargo2, Raúl Maneyro1 
	Sex does not affect tail autotomy in lacertid lizards
	Panayiotis Pafilis1,*, Kostas Sagonas2, Grigoris Kapsalas1, Johannes Foufopoulos3, Efstratios D. Valakos4
	Fire salamander (Salamandra salamandra) males’ activity during breeding season: effects of microhabitat features and body size
	Raoul Manenti*, Andrea Conti, Roberta Pennati
	Call variation and vocalizations of the stealthy litter frog Ischnocnema abdita (Anura: Brachycephalidae)
	Pedro Carvalho Rocha1,2,*, João Victor A. Lacerda2,3, Rafael Félix de Magalhães2,3, Clarissa Canedo4, Bruno V. S. Pimenta5, Rodrigo Carrara Heitor6, Paulo Christiano de Anchieta Garcia2,3
	Feeding ecology of two sympatric geckos in an urban area of Northeastern Brazil
	José Guilherme G. Sousa1, Adonias A. Martins Teixeira2,*, Diêgo Alves Teles2, João Antônio Araújo-Filho2 and Robson Waldemar Ávila3
	A pattern-based tool for long-term, large-sample capture-mark-recapture studies of fire salamanders Salamandra species (Amphibia: Urodela: Salamandridae)
	Jeroen Speybroeck1,*, Koen Steenhoudt2,$
	Skeletal variation within the darwinii group of Liolaemus (Iguania: Liolaemidae): new characters, identification of polymorphisms and new synapomorphies for subclades
	Linda Díaz-Fernández*, Andrés S. Quinteros, Fernando Lobo
	Marking techniques in the Marbled Newt (Triturus marmoratus): 
PIT-Tag and tracking device implant protocols
	Hugo Le Chevalier1, Olivier Calvez2, Albert Martínez-Silvestre3, Damien Picard4, Sandra Guérin4,5, Francis Isselin-Nondedeu6, Alexandre Ribéron1, Audrey Trochet1,2,*
	Evidence for directional testes asymmetry in Hyla gongshanensis jindongensis
	Qing Gui Wu1, Wen Bo Liao2,*
	The advertisement call of Pristimantis subsigillatus (Anura, Craugastoridae)
	Florina Stănescu1,4, Rafael Márquez2, Paul Székely3,4,*, Dan Cogălniceanu1,4,5
	Nematodes Infecting Anotosaura vanzolinia (Squamata: Gymnophthalmidae) from Caatinga, northeastern Brazil
	Bruno Halluan S. Oliveira¹, Adonias A. Martins Teixeira¹,*, Romilda Narciza M. Queiroz¹, João A. Araujo-Filho¹, Diêgo A. Teles¹, Samuel V. Brito2, Daniel O. Mesquita¹
	Where is my place? Quick chorus structure assembly in the European tree frog
	Michal Berec
	A possible mutualistic interaction between vertebrates: frogs use water buffaloes as a foraging place 
	Piotr Zduniak1,*, Kiraz Erciyas-Yavuz2, Piotr Tryjanowski3
	Good vibrations: A novel method for sexing turtles
	Donald T. McKnight1,2,*, Hunter J. Howell3, Ethan C. Hollender1, and Day B. Ligon1
	Errata to
	Mecke, S., Hartmann, L., Mader, F., Kieckbusch, M., Kaiser, H. (2016): Redescription of Cyrtodactylus fumosus (Müller, 1895) (Reptilia: Squamata: Gekkonidae), with a revised identification key to the bent-toed geckos of Sulawesi. Acta Herpetologica 11(2):