Skip to main content
NCBI home page
Helminthologia logoLink to Helminthologia
. 2021 Dec 25;58(4):356–363. doi: 10.2478/helm-2021-0042

Parasitic Infection Patterns in Coleodactylus Meridionalis (Squamata: Sphaerodactylidae) from Atlantic Forest Fragments, Northeast of The Neotropical Region

A A M Teixeira 1,*, N K S Sampaio 3, J A Araujo-Filho 2, D A Teles 2, W O Almeida 3, D O Mesquita 2, S V Brito 1
PMCID: PMC8776295  PMID: 35095311

Summary

Studies that seek to understand which factors influence the patterns of infection in the lizard Coleodactylus meridionalis are non-existent. In this way, we recorded the infection rates for these lizards from three different sized fragments of the Atlantic rainforest and investigated if there is influence of the size, mass and sex of the host regarding the endoparasite abundance. In addition, we investigated if there were possible associations between the host’s diet and parasitism, by calculating the diet niche breadth (based on the prey number of pooled stomachs) for each host population and comparing the diet between fragments and sexes (from the three sampled fragments). We collected 38 lizards across the three sampled forest fragments. We only found parasites in the lizards sampled from the smallest of the three forest fragments which included: Physaloptera lutzi, Haplometroides odhneri and Oligacanthorhynchus sp. For this population, lizards with greater length and body mass have a greater endoparasite abundance. In addition, based on the results obtained in our study, the diet of the lizards varies in food composition between sampled populations. Finally, knowing that among the infected lizards there is no sexual dimorphism in relation to size and body mass and that the stomach sampling for this population is insufficient to calculate the indexes related to the food niche; we used the number of prey lizards from all populations, thus we were able to associate the fact that female lizards have a greater endoparasite abundance due to variations in food composition between sexes.

Keywords: Helminths, Gecko, Diet, Neotropical Region, Brazil

Introduction

Belonging to the family Sphaerodactylidae, lizards of the Coleodactylus genus Parker, 1926 are very small, with some species reaching an average of 32 mm in total length (Goncalves et al., 2012). They can be found in areas of the Amazon rainforest (Avila-Pires, 1995), Atlantic forest (Teixeira et al., 2020), including mesic regions located in the Caatinga and the Cerrado (Colli et al., 2002; Ribeiro et al., 2013). However, most studies on Coleodactylus are aimed to test systematic and phylogenetic hypotheses (Correia et al., 2016), are related with surveys about their geographic distributions (Ribeiro et al., 2013), followed by scarce records on food composition and spatial niche (Werneck et al., 2009). In addition, only two studies present simple surveys on endoparasites infecting these lizards (Ávila & Silva, 2013; Teixeira et al., 2020), but without investigating, if life history traits, such as sex, body mass, size, and host diet, influence their infection patterns.

Parasites are one of the main regulators of their host populations, and can cause simple infections with low prevalence (Teixeira et al., 2018a), reduced fitness, organ damage and death (Almeida et al., 2008). Also, due to the aggregate distribution character adopted by most parasite species, environmental changes accelerated by human action, such as habitat fragmentation and loss of biodiversity (Lafferty & Kuris, 2005), can cause parasite species to disappear before the actual extinction of their hosts (Lyles & Dobson, 1993), harming the meticulous balance present in this relationship. Coleodactylus meridionalis (Boulenger, 1988) is considered one of the smallest lizards in South America, reaching less than 30 mm in length; however, it has a wide distribution throughout northeastern Brazil, being found mainly in Atlantic Forest habitats (Ribeiro et al., 2013). In addition, they have restricted spatial and food niches, occurring mainly in leaf litter (Oliveira et al., 2015), with isopods being considered their primary food source (Dias et al., 2003).

Despite their wide distribution (Ribeiro et al., 2013), these lizards are considered relictual due to their small size and their incredible ability to camoufl age among the leaves and other fragments of trees in the forests, thus making the collection of sufficient samples for statistical analysis purposes diffi cult (Werneck et al., 2009), which in turn is reflected in the scarcity of existing studies.

For the purpose of our study we focused on describing the parasitic infection patterns in C. meridionalis between fragments of Atlantic rainforest with different sizes. We recorded their infection rates and investigated if there is a relationship between SVL, body mass, host sex and endoparasite abundance. In addition, to identify possible associations between the host diet and parasitism, we calculated the diet niche breadth (based on the prey number of pooled stomachs) for each host population compared the diet similarity (through niche overlap) between fragments and sexes.

Materials and Methods

We collected lizards from three Atlantic forest fragments of different sizes (Fig. 1). The first fragment presents the largest forest area, about 1,058.62 ha – The Private Reserve of Natural Heritage Engenho Gargaú (PRNHEG; 16 specimens collected in September 2016), which is an area belonging to the Japungu Agroindustrial S/A, in the Santa Rita municipality (06° 59’ 52” S; 34° 57’ 30” W).

Fig. 1.

Fig. 1

Open in a new tab

Atlantic Forest fragments sampled in this study, located in the Paraíba state, Brazil.

The second fragment has an area of almost 500.00 ha – The Benjamim Maranhão Botanical Garden (BMBG; six specimens collected in November 2016) is a remnant of forest in the urban area of the João Pessoa municipality (07° 08’ 08” S; 34° 51’ 37” W). Finally, the last fragment is an area of about 47.50 ha – The Area of Relevant Ecological Interest Mata de Goiamunduba (AREIMG; 16 specimens collected in October 2016) is located in the Bananeiras municipality (06° 45’ 03.78” S; 35° 38’ 00.06” W). All the above forest fragments are located in the State of Paraíba, Northeastern Brazil and have an average annual rainfall of 1,521 mm and an average annual temperature of 24.2 °C.

We sampled each fragment during 20 consecutive days, between 8:00 a.m. to 4:00 p.m., due to the lack of visibility inside the forest (about 200m from the edge). We captured lizards manually or using pitfall traps (25 traps per study location, mounted in microhabitats more conducive to capturing specimens). Subsequently, we euthanized lizards with a lethal injection of 2 % lidocaine hydrochloride, and measured the snout-vent length (SVL) with a precision calliper to the nearest 0.01 mm and the mass using a decimal precision digital scale, fixed with 10 % formaldehyde, stored in 70 % alcohol and housed in the Coleção Herpetológica da Universidade Federal da Paraíba - CHUFPB.

The lizards were dissected under magnifying glass, and their respiratory and gastrointestinal tracts were examined for the presence of endoparasites. Endoparasites found were counted and their sites of infection recorded. For identification, nematodes were mounted on temporary slides with lactophenol, while trematodes were serially dehydrated through increasing concentrations of alcohol and stained with acetic carmine and later mounted on slides with eugenol (Kritsky et al., 1986). Acanthocephalans, on the other hand, were mounted on slides in a glycerol medium (MacAllister & Bursey, 2007). Then, we stored all helminths in 99.7 % alcohol and housed in Coleção de Invertebrados Paulo Young, in Universidade Federal da Paraíba, Brazil (UFPB-NEM: 03, 04; UFPB-DIG: 03, 04, 05; UFPB-ACA: 01).

We calculated prevalence indices (% of infected hosts) and mean intensity of infection using the methods described in Bush et al. (1997). To check if the SVL and body mass influence the endoparasite abundance, we used generalised linear mixed models (GLMMs) (Bates et al., 2014). In the first model, the endoparasite abundance corresponds to the response variable and, consequently, the SVL corresponds to the independent variable. In addition, host gender was included as a random effect. In the following model, the endoparasite abundance corresponds to the response variable, body mass corresponds to the independent variable, and host gender is a random effect. In both models, we used the Poisson distribution and log link function.

Posteriorly, we create four more models using the generalised linear model (GLM). In this case, the first model was used to verify if endoparasite abundance varies between male and female adult (using only the lizards from AREIMG). The second model was used to verify if the SVL varies between the sampled locations. Finally, the third and fourth models were used to verify the existence of sexual dimorphism related to SVL and body mass (using only the lizards from AREIMG). In the first GLM model, we used the Poisson distribution and log link function; in the other GLM models, we used the Gamma distribution and inverse link function (Bolker et al., 2009).

We analysed the stomach contents using a magnifying glass and identified the prey to the lowest possible taxonomic category. The niche breadth was based on the prey number, since prey items were too fragmented to accurately calculate volume estimates. We calculated the percentages of each prey category per species, from which we obtained the numerical niche breadths using the inverse of the Simpson diversity index (1949):

B=1i=1nPi2

Where i is the prey category, P is the proportion of prey category i, and n is the number of categories. We compared the diet niche breadth of lizards between males and females and sampled areas, based on the prey number of pooled stomachs.

The diet niche overlap among males and females and the similarity between the areas was calculated using the Pianka overlap index (Pianka, 1973):

jk=i=1npijpiki=1npij2i=1npik2

where Pij and Pik are the consumption rate of the category of prey i, with j and k representing sexes and areas compared. The Pianka overlap index ranges from zero (no overlap/similarity) to one (total overlap/similarity). We performed all analyses in the Software “R”, using the packages ‘lme4’ (Bates et al., 2014) and “R commander”. Throughout the text, means appear as ± 1 SD.

Ethical Approval and/or Informed Consent

The present research has complied with all the relevant national regulations and institutional policies for the care and use of animals. Permits for capturing of the lizards and analysing of the endoparasites used in this study were released by SISBIO-IBAMA (no: 54378/3, authentication code: 78752298; no: 56863-1, authentication code: 47783645), SUDEMA (no: 004/2016, process no. 5376/16), and Benjamim Maranhão Botanical Garden-BMBG (no: 003/2016/JBBM/SUDEMA).

Results and Discussion

Considering all areas together, we examined 38 C. meridionalis, including 11 adult females (SVL = 22.51 ± 2.0 mm), 25 adult males (SVL = 23.38 ± 1.9 mm) and two juveniles (SVL = 20.85 and 20.8 mm) (Table 1). Of the three populations analysed, only the AREIMG specimens were parasitised. We found 152 endoparasites, with 68 infecting eight adult males (Prevalence = 80 %), 82 infecting three adult females (Prevalence = 75 %) and two infecting one juvenile (Prevalence = 50 %). Twelve of the 16 lizards from AREIMG were parasitised by the nematode Physaloptera lutzi Cristofaro, Guimarães and Rodrigues, 1976 (prevalence of 75 %; mean intensity of infection of 12.5 ± 12.95), one lizard was infected with two trematodes Haplometroides odhneri Ruiz and Perez, 1959 (prevalence of 6.2 %) and one lizard was infected with one acanthocephalus Oligacanthorhynchus sp. Travassos, 1915 (prevalence of 6.2 %). The mean intensity of infection (OVERALL) was 12.66 ± 12.86.

Table 1.

Basic morphometric data of C. meridionalis from three sampled areas.

PRNHEG BMBG AREIMG
SVL Mass SVL Mass SVL Mass
Male 22.21 ± 1.23 0.25 ± 0.06 21.59 ± 1.65 0.18 ± 0.06 25.02 ± 2.2 0.26 ± 0.06
Female 24.21 ± 1.02 0.29 ± 0.07 - - 25.06 ± 2.13 0.28 ± 0.06
Juvenile - - - - 20.85 and 20.8 0.2 and 0.15
Open in a new tab

We found that the endoparasite abundance is correlated with SVL (R2m= 0.06; R2c= 0.9; z-value= 2.176; p-value= 0.0295) and body mass of the hosts (R2m= 0.33; R2c= 0.89; z-value= 5.335; p-value < 0.0001). In both cases, the greater the body mass and SVL of the lizards, the greater the endoparasite abundance it can support (Fig. 2).

Fig. 2.

Fig. 2

Open in a new tab

Relationships between endoparasite abundance, SVL (A) and body mass (B), only for lizards from AREIMG.

The results obtained by the GLM models revealed that female hosts harbor a greater endoparasite abundance compared to male hosts (z-value= -6.821; p-value < 0.0001) (Fig. 3); on the other hand, lizards from AREIMG are larger (SVL) than those of the other two populations (t-value= -4.671; p-value < 0.0001) (Fig. 4); in addition, the C. meridionalis population from AREIMG does not present sexual dimorphism in relation to the SVL (t-value= 0.03; p-value= 0.977) and body mass (t-value= 0.471; p-value= 0.646). Lizards collected in AREIMG present the greatest diet niche breadths (based on the prey number of pooled stomachs) among the three sampled locations. On the other hand, male lizards also have greater numerical niche breadths when compared to females (Table 2). Finally, we found a low numerical niche overlap among the three sampled areas (AREIMG/PRNHEG: 0.19; AREIMG/ BMBG: 0.005; PRNHEG/BMBG: 0.00) and between male and female lizards (0.05), from the grouping of the food composition of all areas. Knowing that all species of helminths recorded in this study have a heteroxene life cycle, the differences in food composition between male and female lizards and the between the studied areas may help to understand the patterns of infection present in C. meridionalis lizard.

Fig. 3.

Fig. 3

Open in a new tab

Endoparasite abundance among females and males from AREIMG.

Fig. 4.

Fig. 4

Open in a new tab

Snout-vent length (SVL) of the three populations of C. meridionalis sampled in this study.

Table 2.

Diet composition, prey number and IVI (importance value index) from three populations of Coleodactylus meridionalis including sex.Niche breadth based on the prey number of pooled stomachs “Niche N° A” for each site at the bottom of the table.

Diet BMBG PRNHEG AREIMG Males Females
Araneae - 5/36.44 1/7.38 5/23.96 1/8.43
Diptera - 1/8.28 1/2.99 2/5.56 -
Formicidae 48/44.1 - - 48/20.95 -
Homoptera 2/7.94 - - 2/2.32 -
Hymenoptera - 1/12.13 - - 1/12.89
Insect larva 1/35.15 - 3/11.71 4/16.01 -
Insect egg - - 6/7.79 6/4.38 -
Isopoda - 3.35.71 5/34.09 2/5.17 6/69.96
Isoptera - - 14/20.45 11/8.99 -
Orthoptera 1/12.78 - 2/5.87 3/6.82 -
Psocoptera - - 7/9.68 7/5.78 -
Scorpiones - 1/7.42 - - 1/8.67
Niche N° A 1.73 3.27 4.73 3.14 2.07
Open in a new tab

Habitat fragmentation is one of the processes that most threatens biodiversity (Fischer et al., 2005; Pineda & Halffter, 2004). In these environments, dense host populations may face direct and increased parasitic pressures (Primack & Rodrigues, 2006). The AREIMG presents the smallest area among the studied fragments. In this way, the hosts can use specific sites more frequently (Leu et al., 2010), providing a greater probability of a meeting between these parasites and their hosts (Kerr & Bull, 2006). In the case of endoparasites with heteroxenous life cycles, as in the present study, the higher the density of the hosts, the greater the chances of infection because of the limitations that prevent the transmission of the parasite between intermediate and final hosts are reduced (Buck et al., 2017).

In addition, smaller hosts are less susceptible to harboring large parasite abundance (Kuris et al, 1980). Size and body mass are factors that have been considered in an attempt to explain patterns of endoparasite abundance in vertebrates (George‐Nascimento et al., 2004; Poulin, 2007). The present study showed a significant positive relationship when we separately compare body mass and SVL with the endoparasite abundance in C. meridionalis. Theoretically, larger hosts with greater body mass, have the capacity to offer more resources for the development and reproduction of parasites (George‐Nascimento et al., 2004; Poulin, 2007). Furthermore, the difference in C. meridionalis SVL measurements between the areas is also an aspect that may be associated with infection only in lizards of the AREIMG fragment, with the lizards in this population being larger than those in the other two areas.

However, as mentioned by Patterson (2008), the mass and size of the host does not always correspond to greater endoparasite abundance, because ecological, behavioural and phylogenetic aspects can also be linked to the differences in endoparasite abundance and diversity. Furthermore, Price (1990) suggests that smaller hosts complete their life cycles in less time, also decreasing the time for the establishment of abundant parasite populations.

According to Kuris et al. (1980), the host body can be considered an island for parasites, and diversity may be correlated with size. Coleodactylus meridionalis is a small lizard, and in the present study obeys the standards already described in the literature, with low parasite richness; this is commonly represented by the following lizards: Anotosaura vanzolinia Dixon, 1974 (Squamata: Gymnophthalmidae) with an average SVL of 36 mm; Liolaemus lutzae Mertens, 1938 (Squamata: Liolaemidae), 50 mm of SVL; Aspronema dorsivittatum (Cope, 1862) (Squamata: Scincidae) 64 mm of SVL; Phyllopezus lutzae (Loveridge, 1941) (Squamata: Phyllodactylidae) 42 mm of SVL and Dryadosaura nordestina Rodrigues, Xavier Freire, Machado Pellegrine and Sites, 2005 (Squamata: Gymnophthalmidae) 40 mm of SVL, which harbor up to three parasite species (Ávila et al., 2010; Oliveira et al., 2017; Rocha, 1995; Rocha et al., 2003; Teixeira et al., 2018b).

This pattern may be explained by specific sites of infection only being available within larger hosts due to potential greater niche heterogeneity, which thus facilitates segregation of microhabitats (Kuris et al., 1980).

Our results supports previous studies of parasitic fauna associated with small lizards, since we found three species of helminths infecting C. meridionalis from Atlantic Forest: Physaloptera lutzi (Nematoda: Physalopteridae), Haplometroides odhneri (Trematoda: Plagiorchiidae) and Oligacanthorhynchus sp. (Acanthocephala: Oligacanthorhynchidae). Heteroxenic species of the genus Physaloptera are reptiles (Ávila & Silva, 2010; Teixeira et al., 2017; Teixeira et al., 2018a) and amphibian parasites (Campião et al., 2014) in Brazil. The trematode H. odhneri has previously been recorded in snakes (Silva et al., 2005; Silva & Barrella, 2002), and recently in lizards (Teixeira et al., 2018b). In addition, Oligacanthorhynchus sp. has records infecting reptiles and amphibians in South America (Smales, 2007).

The hosts are mainly infected through diet, when the parasites present heteroxenous cycles (Martin et al., 2005). Based on the results obtained in our study, the diet of the lizards vary in food composition between sampled populations, with low numerical niche overlap, and the numerical niche breadths being highest in the AREIMG population, which may also explain the parasitism only occurring in this area. The AREIMG lizards consumed eight categories of prey, with PRNHEG consuming five and BMBG four, suggesting that the hosts of the population in which endoparasites were found consumed a greater diversity of food items. This corroborated the results of Brito et al. (2014), which presented a higher parasite diversity in lizards with higher food diversity.

Finally, the endoparasite abundance is related to host sex, with females being more parasitised than males. Since the lizards from the AREIMG fragment do not show sexual dimorphism with respect to SVL and body mass, we understand that possibly the host diet may be related to the differences in the endoparasite abundance present between males and females of C. meridionalis (Aho, 1990; Fontes et al., 2003; Pereira et al., 2012; Zuk & McKean, 1996). However, we emphasize that this was an speculation on our part, because the patterns obtained for both indexes, niche breadth and food niche overlap between the sexes, were based on the stomach contents of all lizards from the three sampled fragments.

Acknowledgments

We would like to thank Silva RJ for his help in identifying the trematode. We thank CNPq for research fellowships to AAMT (PDCTR/FAPEMA 301692/2021-1), WOA (302429/2015-8), DOM (306541/2017-3). We also appreciate the help of RPNNEG and BMBG employees.

Footnotes

Conflict of Interest.

Authors state no conflict of interest.

References

  1. AHO J.M. ESCH G.W., BUSH A.O., AHO J.M. Parasite communities: patterns and processes. London, England: Chapman and Hall; 1990. Helminth communities of amphibians and reptiles: comparative approaches to understanding patterns and processes. [Google Scholar]
  2. ALMEIDA W.O., FERREIRA F.S., GUARNIERI M.C., BRITO S.V.. Porocephalus species (Pentastomida) infecting Boa constrictor (Boidae) and Lachesis muta (Viperidae) in northeastern Brazil. Biotemas. 2008;21:165–168. [Google Scholar]
  3. ANDRADE-LIMA D. Biological Diversification in the Tropics. New York, USA: Columbia University Press; 1982. Present day forest refuges in Northeastern Brazil. PRANCE, G.T. [Google Scholar]
  4. AVILA-PIRES T.C.S.. Lizards of Brazilian Amazonia (Reptilia: Squamata) Zool. Verh. 1995;299:1–706. [Google Scholar]
  5. ÁVILA R.W., ANJOS L.A., GONÇALVES U., FREIRE E.M.X., ALMEIDA W.O., SILVA R.J.. Nematode infection in the lizard Bogertia lutzae (Loveridge, 1941) from the Atlantic forest in north-eastern Brazil. J. Helminthol. 2010;84:199–201. doi: 10.1017/S0022149X09990538. [DOI] [PubMed] [Google Scholar]
  6. ÁVILA R.W., SILVA R.J.. Checklist of helminths from lizards and amphisbaenians (Reptilia, Squamata) of South America. J. Venom. Anim. Toxins. incl. Trop. Dis. 2010;16:543–572. doi: 10.1590/S1678-91992010000400005. [DOI] [Google Scholar]
  7. ÁVILA R. W., SILVA R. J.. Helminths of lizards from the municipality of Aripuana in the southern Amazon region of Brazil. J. Helminthol. 2013;87:12–6. doi: 10.1017/S0022149X11000769. [DOI] [PubMed] [Google Scholar]
  8. BATES D., MÄCHLER M., BOLKER B.M., WALKER S.C.. Fitting linear Mixed-Effects Models Using lme4. J. Stat. Softw. 2014;67:1–48. doi: 10.18637/jss.v067.i01. [DOI] [Google Scholar]
  9. BOLKER B.M., BROOKS M.E., CLARK C.J., GEANGE S.W., POULSEN J.R., STEVENS M.H.H., WHITE J.-S.S.. Generalized linear mixed models: a practical guide for ecology and evolution. Trends Ecol. Evol. 2009;24:127–135. doi: 10.1016/j.tree.2008.10.008. [DOI] [PubMed] [Google Scholar]
  10. BRITO S.V., CORSO G., ALMEIDA A.M., FERREIRA F.S., ALMEIDA W.O., ANJOS L.A., MESQUITA D.O., VASCONCELLOS A.. Phylogeny and micro-habitats utilized by lizards determine the composition of their endoparasites in the semiarid Caatinga of Northeast Brazil. Parasitol. Res. 2014;113:3963–3972. doi: 10.1007/s00436-014-4061-z. [DOI] [PubMed] [Google Scholar]
  11. BUCK J.C., HECHINGER R.F., WOOD A.C., STEWART T.E., KURIS A.M., LAFFERTY K.D.. Host density increases parasite recruitment but decreases host risk in a snail–trematode system. Ecology. 2017;98:2029–2038. doi: 10.1002/ecy.1905. [DOI] [PubMed] [Google Scholar]
  12. BUSH A.O., LAFFERTY K.D., LOTZ J.M., SHOSTAK A.W.. Parasitology meets ecology on its own terms: Margolis et al. revisited. J. Parasitol. 1997;83:575–583. doi: 10.2307/3284227. [DOI] [PubMed] [Google Scholar]
  13. CAMPIÃO K.M., MORAIS D.H., DIAS O.T., AGUIAR A., TOLEDO G.M., TAVARES L.E.R., SILVA R.J.. Checklist of Helminth parasites of Amphibians from South America. Zootaxa. 2014;3843:1–93. doi: 10.11646/zootaxa.3843.1.1. [DOI] [PubMed] [Google Scholar]
  14. CASTRO D.P., RODRIGUES J.F.M., BORGES-LEITE M.J., LIMA D.C., BORGES-NOJOSA D.M.. Anuran diversity indicates that Caatinga relictual Neotropical forests are more related to the Atlantic Forest than to the Amazon. PeerJ — J. Life Env. Sci. 2019;11:1–16. doi: 10.7717/peerj.6208. [DOI] [PMC free article] [PubMed] [Google Scholar]
  15. COLLI G.R., BASTOS R.P., ARAUJO A.F.B. OLIVEIRA P.S., MARQUIS R.J. The cerrados of Brazil: ecology and natural history of a neotropical savanna. New York, USA: Columbia University Press; 2002. The character and dynamics of the Cerrado herpetofauna. [Google Scholar]
  16. CORREIA L.L., GAMBLE T., LANDELL M.F., MOTT T.. Indels ascertain the phylogenetic position of Coleodactylus elizae Gonçalves, Torquato, Skuk & Sena, 2012 (Gekkota: Sphaerodactylidae) Zootaxa. 2016;4084:147–150. doi: 10.11646/zootaxa.4084.1.9. [DOI] [PubMed] [Google Scholar]
  17. DIAS E.J.R., VARGEM M.M.F., ROCHA C.F.D.. Coleodactylus meridionalis (NCN) Diet. Herpetol. Rev. 2003;34:142–143. [Google Scholar]
  18. FISCHER J., LINDENMAYER D.B., BARRY S., FLOWERS E.. Lizard distribution patterns in the Tumut fragmentation “Natural Experiment” in south-eastern Australia. Biol. Conserv. 2005;123:301–315. doi: 10.1016/j.biocon.2004.11.018. [DOI] [Google Scholar]
  19. FONTES A.F., VICENTE J.J., KIEFER M.C., VAN SLUYS M.. Parasitism by Helminths in Eurolophosaurus nanuzae (Lacertilia: Tropiduridae) in an Area of Rocky Outcrops in Minas Gerais State, Southeastern Brazil. J. Herpetol. 2003;37:736–741. doi: 10.1670/6803AN. [DOI] [Google Scholar]
  20. GEORGE‐NASCIMENTO M., MUNOZ G., MARQUET P.A., POULIN R.. Testing the energetic equivalence rule with helminth endoparasites of vertebrates. Ecol. Lett. 2004;7:527–531. doi: 10.1111/j.1461-0248.2004.00609.x. [DOI] [Google Scholar]
  21. GONCALVES U., TORQUATO S., SKUK G., SENA G.A.. A new species of Coleodactylus Parker, 1926 (Squamata: Sphaerodactylidae) from the Atlantic Forest of northeast Brazil. Zootaxa. 2012;3204:20–30. [Google Scholar]
  22. KERR G.D., BULL C.M.. Interactions between climate, host refuge use, and tick population dynamics. Parasitol. Res. 2006;99:214–222. doi: 10.1007/s00436-005-0110-y. [DOI] [PubMed] [Google Scholar]
  23. KRITSKY D. C., THATCHER V. E., BOEGER W. A.. Neotropical monogenea. 8. revision of urocleidoides (Dactylogyridae, Ancyrocephalinae). Proc. Helminthol. Soc. Wash. 1986;53:1–37. [Google Scholar]
  24. KURIS A.M., BLAUSTEIN A.R., ALIO J.J.. Hosts as islands. Am. Nat. 1980;116:570–586. [Google Scholar]
  25. LAFERTY K.D., KURIS A.M. THOMAS F., RENAUD F., GUÉGAN J.F. Parasitism and Ecosystems. New York, USA: Oxford University Press; 2005. Parasitism and environmental disturbances. [Google Scholar]
  26. AHO J.M. BUSH A.O., AHO J.M. Parasite communities: patterns and processes. London, England: Chapman and Hall; 1990. Helminth communities of amphibians and reptiles: comparative approaches to understanding patterns and processes. ESCH, G.W. [Google Scholar]
  27. LEU S.T., KAPPELER P.M., BULL C.M.. Refuge sharing network predicts ectoparasite load in a lizard. Behav. Ecol. Sociobiol. 2010;64:1495–1503. doi: 10.1007/s00265-010-0964-6. [DOI] [PMC free article] [PubMed] [Google Scholar]
  28. LYLES A.M., DOBSON A. P.. Infectious disease and intensive management: population dynamics, threatened hosts, and their parasites. J. Zoo Wildl. Med. 1993;24:315–326. [Google Scholar]
  29. MCALLISTER C.T., BURSEY C.R.. Some nematode and acanthocephalan parasites of the longnose leopard lizard, Gambelia wislizenii (Lacertilia: Crotaphytidae), from Arizona, California, and Texas, with a summary of the helminths reported from this host. Comp. Parasitol 2007;,74:179–84. doi: 10.1654/4230.1. [DOI] [Google Scholar]
  30. MARTIN J.E., LLORENTE G.A., ROCA V., CARRETERO M.A., MONTORI A., SANTOS X., ROMEU R.. Relationship between diet and helminths in Gallotia caesaris (Sauria: Lacertidae) Zoology. 2005;108:121–130. doi: 10.1016/j.zool.2005.03.002. [DOI] [PubMed] [Google Scholar]
  31. OLIVEIRA B.H.S., QUEIROZ R.N.M., MESQUITA D.O.. Communal nests and hatchling size of Coleodactylus meridionalis (Squamata: Sphaerodactylidae) in a Caatinga area, Brazil. Herpetol. Notes. 2015;8:125–128. [Google Scholar]
  32. OLIVEIRA B.H.S., TEIXEIRA A.A.M., QUEIROZ R.N.M., ARAUJO FILHO J.A., TELES D.A., BRITO S.V., MESQUITA D.O.. Nematodes infecting Anotosaura vanzolinia (Squamata: Gymnophthalmidae) from Caatinga, northeastern Brazil. Acta Herpetol. 2017;12:103–108. doi: 10.13128/Acta_Herpetol-18765. [DOI] [Google Scholar]
  33. PATTERSON B.D., DICK C.W., DITTMAR K.. Parasitism by bat flies (Diptera: Streblidae) on neotropical bats: effects of host body size, distribution, and abundance. Parasitol Res. 2008;103:1091–1100. doi: 10.1007/s00436-008-1097-y. [DOI] [PubMed] [Google Scholar]
  34. PEREIRA F.B., SOUSA B.M., LIMA S.S.. Helminth Community Structure of Tropidurus torquatus (Squamata: Tropiduridae) in a Rocky Outcrop Area of Minas Gerais State, Southeastern Brazil. J. Parasitol. 2012;98:6–10. doi: 10.1645/GE-2689.1. [DOI] [PubMed] [Google Scholar]
  35. PIANKA E.R.. The Structure of Lizard Communities. Annu. Rev. Ecol. Evol. Syst. 1973;4:53–74. [Google Scholar]
  36. PINEDA E., HALFFTER G.. Species diversity and habitat fragmentation: frogs in a tropical montane landscape in Mexico. Biol. Conserv. 2004;117:499. doi: 10.1016/j.biocon.2003.08.009. –. POULIN, R. (2007): Evolutionary Ecology of Parasites. Princeton, New Jersey, Princeton University Press. [DOI] [Google Scholar]
  37. PRICE P.W. ESCH G.W., BUSH A.O., AHO J. Parasite communities: patterns and processes. Chapman and Hall; London, England: 1990. Host populations as resources defining parasite community organization. [Google Scholar]
  38. PRIMACK R.B., RODRIGUES E. Biologia da conservação [Conservation Biology]. Editora Planta. Brazil: 2006. (In Portuguese) [Google Scholar]
  39. RIBEIRO L.B., GOGLIATH M., RODRIGUES R.G., BARRETO R.M., FREIRE E.M.X.. Two new records of Coleodactylus meridionalis (Boulenger, 1888)(Squamata, Sphaerodactylidae) in Brazil, including a map and comments regarding its geographical distribution. Herpetol. Notes. 2013;6:23–27. [Google Scholar]
  40. ROCHA C.F.D.. Nematode parasites of the Brazilian sand lizard, Liolaemus lutzae. Amphib-Reptilia. 1995;16:412–415. [Google Scholar]
  41. ROCHA C.F.D., VRCIBRADIC D., VICENTE J.J., CUNHA-BARROS M.. Helminths infecting Mabuya dorsivittata (Lacertilia, scincidae) from a high-altitude habitat in Itatiaia National Park, Rio de Janeiro State, Southeastern Brazil. Braz. J. Biol. 2003;63:129–132. doi: 10.1590/S1519-69842003000100017. [DOI] [PubMed] [Google Scholar]
  42. SILVA R.J., ANDRADE P.A., MONTEIRO E SILVA H.A., ROSSELLINI M., BARRELLA T.H.. Report on the occurrence of Haplometroides buccicola (Trematoda, digenea, plagiorchiidae) infecting Phalotris lativittatus (serpentes, Colubridae) in Brazil. J. Venom. Anim. Toxins. incl. Trop. Dis. 2005;11:373–379. doi: 10.1590/S1678-91992005000300013. [DOI] [Google Scholar]
  43. SILVA R.J., BARRELLA T.H.. Micrurus frontalis as a new host recorded for Haplometroides odhneri (Trematoda, Digenea, Plagiorchiidae) Rev. Bras. Parasitol. Vet. 2002;11:47–48. [Google Scholar]
  44. SMALES L.R.. Acanthocephala in amphibians (Anura) and reptiles (Squamata) from Brazil and Paraguay with description of a new species. J. Parasitol. 2007;93:392–398. doi: 10.1645/GE937R.1. [DOI] [PubMed] [Google Scholar]
  45. TEIXEIRA A.A.M., BRITO S.V., TELES D.A., RIBEIRO S.C., ARAUJO-FILHO J.A., LIMA V.F., PEREIRA A.M.A., ALMEIDA W.O.. Helminths of the Lizard Salvator merianae (Squamata, Teiidae) in the Caatinga, Northeastern Brazil. Braz. J. Biol. 2017;77:312–317. doi: 10.1590/1519-6984.13515. [DOI] [PubMed] [Google Scholar]
  46. TEIXEIRA A.A.M., FRANZINI L.D., BRITO S.V., ALMEIDA A.M., MESQUITA D.O.. Very low prevalence of infection by Physaloptera lutzi (Nematoda: Physalopteridae) parasitizing Kentropyx calcarata (Squamata: Teiidae), from fragments of Atlantic Forest in Northeast Brazil with a summary of nematodes infecting congeneric species. Herpetol. Notes. 2018a;11:799–804. [Google Scholar]
  47. TEIXEIRA A.A.M., RIUL P., BRITO S.V., ARAUJO FILHO J.A., TELES D.A., ALMEIDA W.O., MESQUITA D.O.. Ecological release in lizard endoparasites from the Atlantic Forest, northeast of the Neotropical Region. Parasitology. 2020;147:491–500. doi: 10.1017/S0031182020000025. [DOI] [PMC free article] [PubMed] [Google Scholar]
  48. TEIXEIRA A.A.M., SILVA R.J., BRITO S.V., TELES D.A., ARAUJO-FILHO J.A., FRANZINI L.D., SANTANA D.O., ALMEIDA W.O., MESQUITA D.O.. Helminths infecting Dryadosaura nordestina (Squamata: Gymnophthalmidae) from Atlantic Forest, northeastern Brazil. Helminthologia. 2018b;55:286–291. doi: 10.2478/helm-2018-0026. [DOI] [PMC free article] [PubMed] [Google Scholar]
  49. WERNECK F.P., COLLI G.R., VITT L.J.. Determinants of assemblage structure in Neotropical dry forest lizards. Austral Ecol. 2009;34:97–115. doi: 10.1111/j.1442-9993.2008.01915.x. [DOI] [Google Scholar]
  50. ZUK M., MCKEAN K.A.. Sex differences in parasite infections: patterns and processes. Int. J. Parasitol. 1996;26:1009–1024. doi: 10.1016/S0020-7519(96)80001-4. [DOI] [PubMed] [Google Scholar]

Articles from Helminthologia are provided here courtesy of De Gruyter

RESOURCES