A Comparison of Multiple Methods for Estimating Parasitemia of Hemogregarine Hemoparasites (Apicomplexa: Adeleorina) and Its Application for Studying Infection in Natural Populations

João P. Maia; D. James Harris; Salvador Carranza; Elena Gómez-Díaz

doi:10.1371/journal.pone.0095010

Abstract

Identifying factors influencing infection patterns among hosts is critical for our understanding of the evolution and impact of parasitism in natural populations. However, the correct estimation of infection parameters depends on the performance of detection and quantification methods. In this study, we designed a quantitative PCR (qPCR) assay targeting the 18 S rRNA gene to estimate prevalence and intensity of Hepatozoon infection and compared its performance with microscopy and PCR. Using qPCR, we also compared various protocols that differ in the biological source and the extraction methods. Our results show that the qPCR approach on DNA extracted from blood samples, regardless of the extraction protocol, provided the most sensitive estimates of Hepatozoon infection parameters; while allowed us to differentiate between mixed infections of Adeleorinid (Hepatozoon) and Eimeriorinid (Schellackia and Lankesterella), based on the analysis of melting curves. We also show that tissue and saline methods can be used as low-cost alternatives in parasitological studies. The next step was to test our qPCR assay in a biological context, and for this purpose we investigated infection patterns between two sympatric lacertid species, which are naturally infected with apicomplexan hemoparasites, such as the genera Schellackia (Eimeriorina) and Hepatozoon (Adeleorina). From a biological standpoint, we found a positive correlation between Hepatozoon intensity of infection and host body size within each host species, being significantly higher in males, and higher in the smaller sized host species. These variations can be associated with a number of host intrinsic factors, like hormonal and immunological traits, that require further investigation. Our findings are relevant as they pinpoint the importance of accounting for methodological issues to better estimate infection in parasitological studies, and illustrate how between-host factors can influence parasite distributions in sympatric natural populations.

Citation: Maia JP, Harris DJ, Carranza S, Gómez-Díaz E (2014) A Comparison of Multiple Methods for Estimating Parasitemia of Hemogregarine Hemoparasites (Apicomplexa: Adeleorina) and Its Application for Studying Infection in Natural Populations. PLoS ONE 9(4): e95010. https://doi.org/10.1371/journal.pone.0095010

Editor: Érika Martins Braga, Universidade Federal de Minas Gerais, Brazil

Received: November 8, 2013; Accepted: March 21, 2014; Published: April 17, 2014

Copyright: © 2014 Maia et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Funding: JPM was funded through a PhD grant (SFRH/BD/74305/2010) supported by a Fundação para a Ciência e a Tecnologia (FCT) doctoral fellowship under the Programa Operacional Potencial Humano – Quadro de Referência Estratégico Nacional funds (POPH-QREN) from the European Social Fund (ESF) and Portuguese Ministério da Educação e Ciência. EG-D was supported by a Juan de la Cierva contract from the Ministerio de Educación y Ciencia, Spain. Financial support was provided by project ERG-PARIS-276838 from the European Commission. DJH is supported by FEDER through the compete program, the project “Genomics and Evolutionary Biology” cofinanced by North Portugal Regional Operational Program (ON.2) under NSRF through the European Regional Development Fund. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: The authors have declared that no competing interests exist.

Introduction

Parasites can be major drivers of host ecology and evolution and play key roles in ecosystem functioning and structure. Parasitism can for example alter host life-history traits and fitness [1], [2], as well as influence predator-prey or competitive interactions between and within species [3]–[5]. However, the ecological niche in which both host and parasite occur is complex and multifaceted, and there is considerably variation in patterns of parasitism in natural populations at multiple spatial and temporal scales [6], from individual to community levels [7], [8]. Natural variation in infection parameters can be due to differences in the environmental exposure to parasites [9], or to variation in the susceptibility or resistance to infection [10]. Investigating the underlying patterns can contribute to a better understanding of the impact and evolution of parasitism [11]–[13], while also providing valuable epidemiological and conservation information.

Importantly, the estimation of biological relevant and realistic infection patterns is constrained by differences in the accuracy, specificity and sensitivity of the detection and quantification protocols used [14], [15]. The use of less accurate protocols may lead to erroneous ecological and epidemiological inferences, which is particularly critical in host-parasite systems with low intensity levels or with mixed parasite infections. In recent years, quantitative PCR (qPCR) has been used in parasitological studies as it allows the simultaneous detection and quantification of parasite DNA from various biological sources, such as host and vector blood and tissues [16]–[20]. Compared to more traditional approaches, such as microscopy or conventional PCR (PCR), qPCR has increased accuracy and sensitivity of detection [21], [22]. Despite the advantages, the use of this quantitative method in parasitology has been primarily used for clinical samples and/or pathogens of human-health and veterinary importance [17]. Although this technique is now routinely applied for clinical studies in domestic animals [21], its applications in wild animal populations, is just beginning to emerge [6], [19], [23]–[25]. More importantly, studies comparing the performance of the different methods under various experimental conditions are generally lacking (but see [15]).

Sympatric and closely related species represent natural model systems and an ideal opportunity where to investigate between-host differences in infection parameters [26]. Closely related species are likely to be susceptible to the same or similar parasite species due to common ancestry, and the same can happen with sympatric host species due to common ecological determinants [27]. In these systems, differences in infection may arise due to inter- and intra-host variation in susceptibility and/or tolerance to infection, while controlling for general environmental differences in exposure. Reptiles have become model organisms for parasitological studies, in part due to their low dispersal potential, and the occurrence of sympatric speciation [28]. Despite the growing number of studies addressing infection variation in animal populations [29]–[32], these remain largely enigmatic in the case of wild reptiles. In reptiles, body size and weight have been commonly used as a proxy measure to explain individual as well as population and species differences in susceptibility and/or tolerance to parasite infection [33]–[37], because it is often positively correlated with host life-history traits such as longevity, survival and fecundity, which relate to fitness [38]. Other factors that might drive variation in parasite infection include host behaviour and morphology [39], [40], immunity [10], [41] and ecology [27], [42]. However, previous studies have shown contrasting patterns of association with those factors [34]–[36], [43], which may be in part due to the effects of sampling and methodological bias, and/or confounding phylogenetic or environmental factors [42], [44], [45].

Hepatozoon (Apicomplexa: Adeleorina), is a highly diverse genus of intracellular hemogregarine parasites with more than 300 species described [46], and the most common and widely distributed hemoparasites found in reptiles [47]. Yet few studies to date have examined prevalence and intensity of infection in wild reptile populations (but see [35], [37], [48]–[51]). Arthropod vectors, such as mites, ticks and mosquitoes, are the definitive hosts in a complex heteroxenous lifecycle that includes a wide range of vertebrates as intermediate hosts [46]. Pathogenesis caused by Hepatozoon infections in reptiles is unclear, with studies reporting from apparently non-detrimental infections in natural hosts [36], [52], to severe and life-threatening illness in unnatural hosts [53]. This has been mostly studied in domestic animals, for which the most common symptoms include anaemia, lethargy, weight loss, weakness and cachexia [54], [55], while the pathogenic effects on wildlife are mostly unknown. In addition, other apicomplexans, such as Schellackia sp. (Apicomplexa: Eimeriorina), are often found at lower prevalence and intensities in wild reptile hosts, and mixed infections with Hepatozoon can also occur [56], [57]. In this study, we investigate Hepatozoon infection parameters in two sympatric closely related lacertid species, Podarcis bocagei and P. hispanica. These two host species present an attractive system because: first, they live in sympatry and, despite having similar ecological requirements, there are apparent preferences for microhabitat: P. hispanica is frequently found on rocks (saxicolous), while P. bocagei is mainly grounddwelling [58], [59]; second, despite being genetically closely related [60], they present considerable morphological differences, with P. bocagei being generally larger [61], [62]; third, size sexual dimorphism has been reported for both species, with adult males being larger than females [62], [63]; and fourth, recent studies report high prevalence of Hepatozoon and low prevalence of Schellackia infections for these species in the Iberian Peninsula [50], [56]. Therefore, this model system provides an ideal scenario for investigating between host-species, sex and inter-individual differences in patterns of Hepatozoon infection, while controlling for confounding factors such as ecology and host and parasite phylogeny.

The objectives of this study are: i) to evaluate the accuracy and sensitivity of different detection methods (microscopy, PCR and qPCR) and protocols (biological source and DNA extraction protocol) for detecting and quantifying hemogregarine parasites in reptile samples, as well as the occurrence of mixed infections, and ii) apply the most sensitive approach, i.e. qPCR, to determine prevalence and intensity of Hepatozoon infection in two sympatric closely related lacertid species, P. bocagei and P. hispanica, and assess the relative role of inter-individual (intra-species) and between-species factors on these parameters.

Materials and Methods

Study species and study site

Samples were collected from two lacertid lizard species, P. bocagei and P. hispanica, from a single location in Gerês, Northern Portugal (41.782340, -8.145140), in July 2011. Capture permits were issued by the ICNB (Instituto da Conservação da Natureza e da Biodiversidade, I.P.), license numbers 67-75/2011/CAPT. These hosts are small, diurnal, insectivorous lizards, with adult snout-vent length (SVL) of 45–65 mm and 37–70, respectively. A total of 87 adult individuals were sampled (51 P. bocagei and 36 P. hispanica, see Table 1). Each individual was handled by experienced herpetologists, a small piece of the tail-tip was collected and, when enough blood was obtained, a blood drop was stored in Whatman filter paper and the rest was used to make a blood smear. No animals were sacrificed. SVL was measured using a vernier caliper, animals were photographed and sex was determined based on the existence of enlarged femoral pores. After processing, animals were released at the site of capture. This protocol has been approved by the ethical committee of the University of Porto. Tissue samples were preserved in 96% ethanol and stored at room temperature and blood drops stored at −20°C. Blood smears were air-dried, fixed with methanol on the day of collection and stained with diluted Giemsa (1∶9 of distilled water) for 55 minutes within a week of collection.

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Table 1. Prevalence and mean intensity of Hepatozoon and Eimeriorina parasites for the two lizard species analysed in this study, estimated using three different methods.

https://doi.org/10.1371/journal.pone.0095010.t001

Microscopic examination

Blood smears were examined using an Olympus CX41 microscope with an in-built digital camera (SC30). Several photographs per slide were taken under the 40× magnification lenses and stitched using cell∧B software (basic image-acquisition and archiving software). Prevalence was estimated as the proportion of infected hosts and intensity of infection was estimated as the number of parasites per 4,000 erythrocytes from a total of 72 blood smears [64], [65]. Counts were done using the manual cell counter plug-in available in the image processing software ImageJ ver. 1.44p [66]. Fig. 1 shows mature intraerythrocytic gamonts of Hepatozoon sp. and sporozoites of Schellackia sp. infecting the two lizard species.

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Figure 1. Parasites found in common wall lizards analysed from Gerês, Portugal.

Hepatozoon sp. infecting erythrocytes from P. bocagei (A), and P. hispanica (B). Schellackia sp. infecting an erythrocyte from P. bocagei (C), and a leukocyte from P. hispanica (D). Scale bar = 5 µm.

https://doi.org/10.1371/journal.pone.0095010.g001

DNA extraction and sample preparation

For the total number of samples (n = 87), DNA was extracted from blood using the Speedtools tissue DNA extraction kit (Biotools, Madrid). In a subset of 47 individuals, in which we compared various methodological approaches, DNA was extracted from two biological sources: blood drops stored in Whatman filter paper (approximately 3 mm by 3 mm) and tail-tip muscle tissue (approximately 2 mm by 2 mm with skin removed). On these samples we used two extraction protocols: the Speedtools commercial kit following manufacturer's instructions, and the standard saline protocol [67]. Briefly, the saline method used consisted of adding 600 µl of lysis buffer (0.5 M tris; 0.1 M EDTA; 2% SDS; pH 8.0) and 10 µl of proteinase K (25 mg/ml) to the cut material, which was incubated at 56°C overnight. After incubation, 300 µl of ammonium acetate (5 M; pH 8.0) was added and centrifuged for 15 min at 14000 rpm at 4°C. The supernatant was carefully transferred to new eppendorf tubes, 600 µl of ice-cold isopropanol was added and samples were frozen between 3 h to overnight. After incubation, samples were centrifuged for 25 min at 14000 rpm at 4°C, and the supernatant was carefully discarded. Then, 1000 µl of ice-cold ethanol (70%) was added and centrifuged for 15 min at 14000 rpm at 4°C. The supernatant was carefully discarded and samples were left to evaporate at room temperature. When completely evaporated, 50 µl of ultra-pure water was added and samples were left to hydrate at ambient temperature in an agitator for 2 h. For qPCR analyses, samples were diluted to 10 ng/µl with nuclease-free water (QIAGEN) using an ND-1000 Spectrophotometer (NanoDrop Technologies, Inc.). Quality of DNA for all samples was verified with the nm wavelength within the excepted range for pure DNA according to the manufacturer's manual (260 nm/280 nm ratio mean was 1.98, and the 260 nm/230 nm ratio mean was 2.1). This standardization procedure allows to control for the amount of host DNA, which can interfere with amplification of parasite DNA [16], [68].

Conventional PCR, sequencing and phylogenetic analysis

PCR amplifications were performed on all 87 samples using primers HepF300 and HepR900 [69] that target part of the Hepatozoon 18 S rRNA gene. The PCR reactions using the Hep primers were run in a 20 µl reaction mixture containing 1 U of GoTaq DNA Polymerase (5 u/µl), 1.5 mM MgCl₂ (25 mM), 0.125 mM of each nucleotide, 1 X GoTaq Flexi Buffer, 0.6 mM of each primer, and 2 µl of DNA. The reaction mix was heated to 94°C for 3 min, and amplification was performed through at 94°C for 30 s, 60°C for 30 s, and 72°C for 1 min, in 35 cycles, with a final 10 min extension at 72°C. Two negatives (one blank and one known Hepatozoon negative) and one positive control (one known Hepatozoon positive) were run with each reaction. Sequencing of the positive PCR products was performed in both directions outsource (Macrogen Europe, The Netherlands). Geneious v6.0.3 was used for contig assembly and visualization of sequences. The “heterozygotes plugin” with 30% peak similarity was used to search for possible heterozygous positions. Consensus sequences for each individual were deposited in GenBank under the accession numbers KJ189387-KJ189433 (Hepatozoon), KJ189382-KJ189385 (Schellackia) and KJ189386 (Lankesterella). One representative of each of the three Hepatozoon haplotypes (KJ189418, KJ189426 and KJ189390), of the two Schellackia haplotypes (KJ189382 and KJ189384), and the single Lankesterella haplotype (KJ189386), were aligned with published data on GenBank using the MUSCLE alignment [70] with default parameters and “Refine Existing Alignment” option implemented in Geneious. The alignment consisted of 75 taxa and was 641 bp long. Two different phylogenetic analyses (Maximum Likelihood and Bayesian Inference) were conducted. Maximum Likelihood (ML) analysis with random sequence addition (100 replicate heuristic searches) was used to assess evolutionary relationships, using the software PhyML 3.0 [71]. Support for nodes was estimated using the bootstrap technique [72] with 1000 replicates. The AIC criterion conducted in jModeltest 0.1.1 [73] was used to choose the model of evolution (TIM1+G). Bayesian analysis was implemented using Mr. Bayes v.3.1 [74] with parameters estimated as part of the analysis. The analysis was run for 10×10⁶ generations, saving one tree with random tree sampling each 1000 generations. All trees prior to reaching stationarity (25% of the run) were discarded as burn-in samples, and the remaining trees were combined in a 50% majority consensus tree.

qPCR design and protocol

qPCR assays for detecting Hepatozoon species in canids have been previously designed [18], [20]. We first tested the former protocol in reptile-infected samples, and we obtained a double dissociation peak in the Melting Curve Analysis (MCA). Therefore we designed a qPCR assay targeting the 18 S rRNA gene of hemogregarine species in reptiles taking into account the variation previously reported in Hepatozoon and other apicomplexans (Fig. S1). For this purpose we designed Hemogregarine specific primers JM4_F (5′-ACTCACCAGGTCCAGACATAGA-3′) and JM5_R (5′-CTCAAACTTCCTTGCGTTAGAC-3′) using Primer3Plus [75]. We constructed a reference plasmid containing the target Hepatozoon 18 S rDNA fragment (171 bp) amplified from a positive P. hispanica individual (JX531917) that we used as amplification standard for the qPCR assay. The PCR product was cloned to a plasmid using the TOPO TA Cloning kit (Invitrogen, California) following the manufacturer's instructions. One Shot TOP10 Competent Cells were used for transformation and we used the Purelink Quick Plasmid Miniprep Kit (Invitrogen, California) to isolate the plasmid (aliquots are available upon request). Successful plasmid integration of the Hepatozoon gene fragment was assessed using M13 primers following manufacturer's instructions. Serial 10-fold dilutions containing from 500,000 to 5 copies of plasmid were performed to produce a standard curve for Hepatozoon quantification that was included in each qPCR plate. A MyiQ qPCR machine (Applied Biosystems) was used with the following protocol: 95°C 10 min, 95°C 10 s, 63°C 20 s, 72°C 25 s (with melting), 95°C 1 min, 63°C 30 s, melting from 63–95°C by increments of 0.2°C every 10 s. Reactions contained iQ SYBR Green supermix at 0.5x, each primer at 0.5 mM, 2 µl of 10 ng/µl genomic DNA, in a total volume mix of 20 µl. To estimate the number of copies in unknown samples, raw qPCR results were exported using the program iQ5 R&D version 2.1 (Biorad) and the baseline threshold was determined individually for each plate using the algorithm implemented in LinRegPCR [76]. Validation was performed by direct sequencing on a total of 33 qPCR positive individuals. These included qPCR positives displaying a single peak (negatives and positives for Hepatozoon from microscopy and PCR) and all those displaying mixed infection peaks. These sequences have been deposited in GenBank under accession numbers KJ189434-KJ189463. For this experiment, samples with all threshold cycles (CTs) higher than 35 were considered negative because repeatability decreased significantly after cycle 35, with most replicates differing by more than one Ct. Mixed infection intensity estimates (n = 6) were discarded from subsequent analyses.

Statistical analyses

Normality tests were performed using Shapiro-Wilk and homogeneity of variances tested using Levene's non-parametric test. To approach normality, infection estimates obtained from qPCR (Hepatozoon copy number) were log-transformed using the formula log (x+1). Fitness of the models was tested by Normal Q-Q plots of the Pearson residuals from the model analysis.

Between methods' comparisons.

We first investigated the correlation between Hepatozoon intensity levels detected by microscopy and qPCR using the Spearman correlation coefficient (n = 66, out of 72 blood smears after excluding 6 mixed infections). We used McNemar's test to compare sensitivity of the three detection methods (n = 87) and the four extraction protocols (n = 47) in estimating Hepatozoon prevalence. Then, to compare Hepatozoon intensity among biological sources and extraction protocols (n = 41, out of the subset of 47 samples after excluding 6 mixed infections) we fitted a Generalized Linear Mixed Model (GZLMM), as recommended for unbalanced data with repeated measures (random effects) [77], with normal distribution and log link function. The full model included copy number as the target variable, the biological source, extraction protocol and their interaction as fixed factors, and subject individuals as random effect. Pairwise LSD mean contrasts for each factor were included in the model.

Between hosts' comparisons.

Previous studies have found various associations between infection parameters and body size [43], [51], and therefore prior to building the models we first examined variation in body size between host species and sexes using ANOVA with Type I sums of squares (SS). For this analysis, body size was the response variable and host species and sexes (and their interaction) were treated as fixed factors. We then tested for inter- and intra-specific associations between body size and intensity of infection using the Spearman correlation coefficient. A positive correlation was found and body size was used as a covariate in all subsequent analyses. Then, using qPCR estimates as a proxy, we investigated differences in infection parameters between the two Podarcis host species and between sexes within each species. Prevalence of Hepatozoon infection between host species, between sexes within each species and between the same sexes of both species (n = 87) was compared using a Chi-square test (http://www.quantpsy.org/chisq/chisq.htm). For intensity comparisons between host species and sexes (n = 81, out of 87 samples after excluding 6 mixed infections), while accounting for the effects of body size, we used a Generalized Linear Model (GZLM) with normal distribution and log link function using Type I SS. The full model included body size, host species and sexes (and their interactions) as fixed factors.

All statistical analyses were conducted in IBM SPSS Statistics 21, except for McNemar tests that were conducted in R (R version 3.0.2, R Development Core Team).

Results

qPCR assay validation

Intensity of Hepatozoon infection estimated by microscopy and qPCR were significantly correlated (ρ = 0.893, P<0.001), with qPCR being much more sensitive and detecting as few as 5 copies of parasite DNA. Mean threshold cycle (Ct) standard deviation (SD) was 0.16, mean efficiency 81.1% (SD±2.6) and mean R² = 0.991 (SD±0.008) (Fig. S2). Mean SD values for intra-assay repeatability for sample replicates was 0.198 (SD±0.147) and 0.192 for plasmid dilution replicates (SD±0.166). Melting Curve Analysis of plasmid dilutions displayed a single peak at 81.4°C and amplification charts were S-shaped. Sequences retrieved from qPCR amplifications were BLASTed on GenBank. Those samples displaying a single melting peak curve all matched Hepatozoon spp. sequences, while the ones displaying two distinct peaks (range from 82.6–83.8°C) presented a mixed electropherogram in the sequencing analyses. These mixed infections detected by qPCR matched those detected by conventional PCR sequencing.

Parasite diversity and identification

A total of 56 sequences were obtained from PCR sequencing with the Hep primers. Of these, 51 BLASTed with previously published GenBank sequences of Hepatozoon spp. (Apicomplexa: Adeleorina), 4 with Schellackia spp. and 1 with Lankesterella spp. (Apicomplexa: Eimeriorina). These were considered positive for PCR prevalence (Table 1). In mixed infections, these conventional PCR primers preferentially amplified Eimeriorina parasites so they resulted in single electropherograms by sequencing analysis. The 47 Hepatozoon sequences (4 were discarded from further analyses due to poor quality) resulted in 3 unique haplotypes (and heterozygous individuals for these haplotypes, see Table S1) that differed in 15 polymorphic segregating sites. These haplotypes clustered within a previously identified Hepatozoon lineage obtained from Western Mediterranean and North African reptiles (Fig. 2). The melting curve analysis (MCA) was able to differentiate between different Apicomplexa genera in mixed infections (see above). But we did not find differences in melting temperatures between the three closely related Hepatozoon haplotypes, which are identical for the targeted fragment in the qPCR assay (Fig. S1). Two haplotypes of Schellackia sp. were obtained, one haplotype from a single individual of P. bocagei was identical to Schellackia sp. from P. hispanica (JQ762306 and JX984676), and the other haplotype (two sequences from P. hispanica and one from P. bocagei) was closely related with two haplotypes from Lacerta schreiberi (JX984674 and JX984675) (Fig. 2). Finally, the single Lankesterella sp. sequence obtained in this study is related with Lankesterella minima from the American bullfrog Lithobates (Rana) catesbeianus (AF080611) and Lankesterella valsainensis from the blue tit Parus caeruleus (DQ390207) (Fig. 2).

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Figure 2. Phylogenetic relationships for the 18 S rRNA gene of the hemoparasites analyzed in this study.

Haplotypes retrieved from this study are in bold. Letters refer to lineages found previously in North African lizards [122].

https://doi.org/10.1371/journal.pone.0095010.g002

Methodological comparison

We first compared the accuracy and sensitivity of different detection methods for estimating Hepatozoon prevalence, including microscopy, PCR and qPCR (Table 1). The qPCR assay gave the highest prevalence estimates and differed significantly from microscopy (n = 72, McNemar Chi² = 17.053, df = 1, P<0.001) and PCR (n = 87, McNemar Chi² = 11.529, df = 1, P<0.001). Microscopy and PCR also differed significantly (n = 72, McNemar Chi² = 4.167, df = 1, P = 0.041). Among molecular methods: 23% (16/69) of qPCR Hepatozoon positives and 75% (3/4) of qPCR Eimeriorina positives were not detected by PCR, while the contrary was found only for 2% (1/51) Hepatozoon and 20% (1/5) Eimeriorinid positives (Table 1 and 2). Hepatozoon negatives for PCR and qPCR (considering only blood and the kit extraction protocol) were also negative by microscopy, but two Eimeriorina positives by microscopy were not detected by PCR (Table 2).

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Table 2. False negatives for each of the three detection methods compared in this study.

https://doi.org/10.1371/journal.pone.0095010.t002

Then, based on the qPCR estimates, we compared the performance of two biological sources (blood and tissue) and two extraction protocols (kit and saline) in estimating Hepatozoon infection for a subset of 47 individuals (Table 3). Prevalence differed significantly for the type of source (McNemar Chi² = 10.083, df = 1, P<0.001 for kit, and McNemar Chi² = 7.692, df = 1, P = 0.003 for saline), but not for the type of extraction protocol (McNemar Chi² = 0, df = 1, P = 1.000 for blood and for tissue). In terms of Hepatozoon intensity of infection, the GZLMM analysis showed that Hepatozoon intensity differed significantly between sources (F = 155.096, df1 = 1, df2 = 160, P<0.001) (Fig. 3C and 3D) and between extraction protocols (F = 4.526, df1 = 1, df2 = 160, P = 0.035), but their interaction was marginally significant (F = 3.736, df1 = 1, df2 = 160, P = 0.055). Pairwise comparisons further show that the two tissue extractions differ significantly (F = 4,980, df1 = 1, df2 = 160, P = 0.027) (Fig. 3B), but not for the two blood extractions (F = 0.046, df1 = 1, df2 = 160, P = 0.830) (Fig. 3A), which shows that the previous differences between extraction protocols for the GZLM analysis are due to differences observed between tissue extractions. That is, for tissue the saline method provides slightly lower Hepatozoon intensity estimates than the kit (Table 3). Overall, however, both protocol extractions result in proportional estimates of Hepatozoon intensity (Fig. 3A and 3B) and provide similar number of false negatives (Table 3). In addition, for the same extraction protocol, tissue provided proportionally lower intensity estimates compared to blood (Fig. 3C and 3D). Finally, blood extractions performed similarly at detecting overall prevalence but differed for samples with extremely low parasitemia levels (Fig. 3A and Table 3).

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Figure 3. Comparison of the performance of various methods in estimating Hemogregarine infection intensity.

The two biological sources: blood (A) and tissue (B), and DNA extraction protocols: kit (C) and saline (D). Each line represents the logged Hepatozoon intensity measurement from qPCR for an individual extraction (n = 41, out of the subset of 47 samples after excluding 6 mixed infections).

https://doi.org/10.1371/journal.pone.0095010.g003

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Table 3. Prevalence and mean intensity levels of Hepatozoon and prevalence of Eimeriorina parasites using different biological sources (blood and tissue) and extraction protocols (kit and saline) on a subset of samples tested with qPCR.

https://doi.org/10.1371/journal.pone.0095010.t003

Between-host differences in infection patterns

ANOVA analyses showed significant differences in body size between host species (F = 11.991, df = 1, P = 0.001), P. bocagei being bigger, and sexes (F = 5.023, df = 1, P = 0.028), males being bigger in size. Given that qPCR and blood-kit DNA extraction provided good estimates of infection parameters for the methodological subset comparison, we used this protocol for investigating the relationship between host-factors and infection patterns. Prevalence was higher in P. hispanica females (89%) than in P. bocagei females (59%) (X² = 4.409, df = 1, P = 0.036), but there were no significant differences between species (X² = 3.434, df = 1, P = 0.064), or sexes (P. bocagei: X² = 3.519, df = 1, P = 0.061; P. hispanica: X² = 0, df = 1, P = 1) (see Table 1). In terms of intensity of infection, intensity was significantly related with body size for both host species (P. bocagei, ρ = 0.521, P<0.001, and P. hispanica, ρ = 0.417, P = 0.014) (Fig. 4). The GZLM analysis showed a significant effect of host species (Wald X² = 8.407, df = 1, P = 0.004) and sexes (Wald X² = 7.208, df = 1, P = 0.007), on Hepatozoon intensity levels, and confirmed a significant effect of the covariate factor body size (Wald X² = 4.254, df = 1, P = 0.039). The interaction between body size and host species was also significant (Wald X² = 4.571, df = 1, P = 0.033), which indicates that the effect of host species on the intensity of infection is body-size dependent (Fig. 4).

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Figure 4. Relationship between Hepatozoon intensity and host body size (SVL).

Different host species are represented by colours and sexes by shapes. Fit lines were calculated from the parameter estimates of a regression model only considering the significant factors (intensity∼body size+host species+sex+host species*body size).

https://doi.org/10.1371/journal.pone.0095010.g004

Discussion

Methodological recommendations

In this study we compared the performance of various detection methods and DNA extraction protocols, and evaluated how the detection method can constrain the estimation of biological relevant infection parameters. First, by comparing various methodological approaches, we found that qPCR was the most accurate and sensitive method for estimating Hepatozoon prevalence and intensity, especially in cases of low intensity levels, which is concordant with previous studies conducted on Plasmodium [21], [22]. To our knowledge, this is the first quantitative PCR assay of Hepatozoon parasites of reptiles, with the few qPCR studies on Hepatozoon focusing on carnivore hepatozoonosis [17], [18], [20], [54]. Second, by comparing various extraction protocols on standardized DNA samples, we show that blood samples provide the best estimates of Hepatozoon prevalence and intensity levels, regardless of the extraction protocol, and should therefore be the preferred collection method during fieldwork when possible. Our results also show that the traditional saline DNA extraction protocol can be used as an effective low-cost alternative to the tested commercial DNA extraction kit, since it provides similar estimations of hemoparasite infections. This result is in agreement with previous parasitological studies using alternative protocols to commercial kits [50], [78]–[80]. At low intensity levels, protocols had different sensitivities, which pinpoints that performing a preliminary methodological comparison prior to the commencement of the study can be a cost/time effective strategy. Finally, the performance of tissue samples was poorer than blood, with higher number of false negatives for an equivalent DNA concentration (i.e. 10 ng/µl of total DNA). However, tissues still represent a valuable biological source in parasitological studies because voucher specimens and tail-tip tissue have been traditionally collected in reptile studies, and can provide information about past infections and the evolution of specific pathogens [81]. For each DNA extraction protocol, Hepatozoon infection intensity from tissue was proportionally lower than blood, probably because a piece of tail-tip muscle contains less DNA, than a blood drop stored in Whatman filter paper. It is possible that increasing the DNA concentration of tissue extractions used in qPCR would yield similar results to blood, but this was not tested in this study. The same applies to tissue extracted with kit and tissue extracted with the saline protocol, the latter providing lower overall estimates of Hepatozoon infection. Thus, we recommend the use of higher DNA concentrations when using tissue samples. Our results highlight the need of comparing multiple methods in a case-base manner as a preliminary step, in order to minimize imperfect detection that can ultimately lead to erroneous ecological and epidemiological inferences [14], [16], [82].

In this study we found mixed infection of Hepatozoon (Adeleorina) with two genera of Eimeriorinid parasites (Schellackia and Lankesterella). These parasites were detected by the three detection methods (microscopy, PCR and qPCR), but with different sensitivities. Conventional PCR using the Hep primers only allow the amplification of either hemogregarines or other apicomplexans, and preferentially amplify non-hemogregarine parasites when present in mixed infections [57]. So this method requires at least one additional PCR run using hemogregarine-specific primers (e.g. HEMO [83]). If mixed infections are suspected, we recommend complementing the qPCR approach with conventional PCR that allows newly discovered parasite lineages to be set in a phylogenetic framework. On the other hand, microscopy and qPCR allow the simultaneous detection and differentiation of mixed infections, but failed to detect a few of the Schellackia positives detected by PCR. The false Eimeriorina negative of the qPCR approach could be due to handling errors (e.g. pipetting) or, most likely, because of the preferential binding of the qPCR primers towards Hepatozoon. Despite the qPCR melting curve analysis allowed us to differentiate between parasite genera, specificity was not high enough to discriminate at lower levels, i.e. between closely related Hepatozoon haplotypes. This result is not unexpected, as the aim of this study was to simultaneously detect and quantify various hemogregarine parasites in reptile samples with high accuracy and sensitivity, so the primer set used herein targets an invariable region of the 18 S rRNA gene (see Fig. S1). Thus, future studies aimed at discriminating between and within closely related hemogregarine species may need to refine the proposed qPCR approach by targeting a more variable region or a faster-evolving gene [84]. But in order to do so, a more comprehensive characterization on hemogregarine diversity and taxonomy in multiple hosts and across populations is needed. Eimeriorina infections estimates agree with previous studies that also report low prevalence of these parasites in P. hispanica [56], [57]. This finding is relevant since these coccidian parasites are poorly studied and taxonomy is controversial in some taxa [85], [86]. The sequences obtained here resemble Schellackia and Lankesterella parasites (Apicomplexa: Lankesterellidae). The fact that they are present in both Podarcis species at low prevalence and low intensities may be an indication of the opportunistic nature of the interaction, and/or the fact that this parasite may have detrimental effects on hosts. Co-infection implications in wildlife hosts remain poorly investigated but interaction among parasite heterospecifics in mixed infections is often asymmetrical [3] and the effects of their coexistence may be more detrimental than the additive effects of single infections, resulting in stronger selective pressures on hosts [8], [9]. More sensitive and accurate approaches such as the qPCR assay developed in this study, which simultaneously detects hemogregarine and eimeriorinid parasites, can allow the investigation of the occurrence of mixed infections in natural populations in a systematic and more standardized way.

Between-host differences in infection patterns

Based on qPCR estimates (from blood-kit DNA extraction) we investigated Hepatozoon infection parameters in two Podarcis sympatric species. Our results show high levels of prevalence with no significant differences between host species and sexes within each species. Prevalence can be determined by the rate at which parasites encounter suitable hosts [9], environmental factors [87] and by the distribution of suitable vectors [88]. Thus, the observed pattern may arise because these hosts' species share the same habitat and are exposed to the same parasites and vectors, both being suitable hosts for hemogregarine parasites. This finding differs however with results from a previous study showing differences in prevalence in these two host species from different locations in the Iberian Peninsula [50]. These contrasting patterns may be the result of the differences between method detection accuracy, as shown in this study, or due to the influence of temporal, ecological, evolutionary and behavioural factors in hemoparasite infection [6], [44]. Interestingly, we found three haplotypes and heterozygous individuals, consistent with what has been previously reported by other studies [50]. The importance of this variation should be further studied as the co-occurrence of various parasite species and lineages within a host may contribute increasing parasite and/or host diversity and speciation [89] and parasite clonal diversity can maintain high parasite diversity in host populations [90]. Clearly, integrative studies that involve all these variables are needed in wild reptiles.

Regarding Hepatozoon intensity of infection, we found that it was positively associated with body size within each host species, which seems to be a common pattern among short-lived reptile species (e.g. Iberolacerta monticola [43], P. lilfordi [51] and Lacerta viridis [91]). Body size has been used as an estimator of age in reptiles [92], [93], with older individuals of the same species usually being larger in size. It is assumed that intensity of infection may increase with longevity due to more encounters with parasites, more time to develop infections and less immunocompetence in older animals [37], [42], [94]. However, this pattern is not linear among hemogregarine infections, especially when considering long-lived reptile species. Studies conducted on snakes [35], [36], [95] and tuataras [96] have found an inverse association to that reported here, with larger individuals having lower intensities. These contrasting infestation patterns may be related to differences in the pathogenesis of hemogregarine infections between short- and long-lived reptiles. In short-lived species, such as lizards, hemogregarine infections are often regarded as non-detrimental to host condition [97], while in long-lived species hemogregarine infection appears linked to detrimental effects on life-history traits, including growth rate, juvenile survival and female reproductive output [35]. These contrasting effects may be due to the continued parasite acquisition through time in larger, and older, individuals, in the case of non-detrimental infections [26], while in detrimental infections only those individuals that manage to reduce or clear infection can have longer lifespans and reach larger sizes [9], [35]. Given the strong relationship of host longevity and body size on parasite infection in reptiles in nature, it would be interesting to investigate hemogregarine infection patterns in species with intermediate size and longevity to determine if such an intermediate parasite infection pattern is found.

When comparing intensity levels between the two species, the smaller sized species (P. hispanica) harboured significantly higher intensity levels of Hepatozoon parasites. The association between body size and intensity of infection differed for the two species, being more pronounced in P. bocagei, for which a lower proportion of smaller animals and a higher proportion of bigger animals, are infected. Also, males had higher intensities than females. Several factors may explain these patterns including: host immunocompetence and susceptibility to infection [41], [98], [99], parasite specialization to both the intermediate [44] and definitive hosts [100]–[102], host microhabitat preference [88], abundance of suitable vectors [101], [103], [104], and behaviour heterogeneity of host species and sexes [9], [40], [105]. In our system, the smaller-sized species, P. hispanica, and males within each species, can be more susceptible to infection and/or can differ immunologically/hormonally, and thus harbour higher hemogregarine intensity levels. Differences in leukocyte counts have been reported between Podarcis species [106], which can result in differential immune responses. Associations between individual- and species- specific immune responses and parasitemia levels for various blood parasite groups have been widely reported in birds [107]–[110], and, to a lesser extent, in reptiles [95], [111]. Likewise, a male-biased pattern is commonly observed in hemoparasite infections, which is often attributed to hormonal and immunocompetence differences between sexes [112]–[114]. Future studies should now look for an association between immunological variables and hemogregarine infection in sympatric species.

Hemoparasite infection parameters can vary temporally and spatially, which is especially important in complex parasite systems that have heteroxenous lifecycles and are vector-borne, such as Hepatozoon. For instance, a cross-sectional study of two malaria parasite species has shown parasite-specific variation in the spatial patterns of disease risk in two closely related sympatric bird species, with consistency between years [115]. Seasonal variations (or environmental variations due to climate change [116]) can not only affect vector abundance [117] and influence rates of parasite development in these vectors [118], but also influence vertebrate host behaviour [119] and host immune condition [120], [121]. So studies on various populations and/or across different seasons and years should be conducted in these sympatric species, provided that this system presents a good host-parasite interaction assessment for comparing differences between species and sexes. Finally, a fundamental question on the biology of these parasites that remains, is to identify and compare host-specificity and competence of the definitive invertebrate host(s) for reptile hemogregarines which is fundamental to better understand the evolutionary ecology and transmission dynamics of these parasites.

Conclusion

Here, we present a qPCR assay to detect and quantify hemogregarine hemoparasites in reptiles, which can also differentiate mixed infections by different apicomplexan genera. We then tested the performance of the qPCR approach in natural settings and compared infection patterns in a pair of lizard species. Our study illustrates that closely related sympatric hosts, for which factors like behaviour, morphology and habitat preferences are well-known, represent a good model for studying among-host variation in infection. Future studies are needed to assess the influence of other intrinsic factors, such as physiological and immunological traits, as well as to investigate the evolutionary and ecological significance of mixed infections. Overall, this study illustrates the importance of using accurate detection and quantification methods for estimating infection parameters, and the need of considering methodological aspects when comparing parasitological data within and between studies. We also advocate that, due to differences in performance between detection methodologies and extraction protocols, preliminary studies should be carried out prior to choosing the most appropriate approach in a case-study basis to avoid erroneous inferences.

Supporting Information

Figure S1.

Sequence alignment of the 18 S rRNA gene fragment targeted by the qPCR assay. Arrows indicate nucleotide positions that differ between major Hepatozoon lineages (see Fig. 2).

https://doi.org/10.1371/journal.pone.0095010.s001

(TIF)

Figure S2.

Standard curve obtained from a six 10-fold serial dilutions of the plasmid containing the 18 S rRNA gene. Numbers correspond to dilutions from 1 (500,000 copies) to 6 (5 copies). Dashed lines indicate the number of copies for an unknown sample determined based on the starting Threshold cycle (Ct).

https://doi.org/10.1371/journal.pone.0095010.s002

(TIF)

Table S1.

Number of haplotypes and heterozygous individuals found in this study. The symbol + indicates when the first haplotype peaks are higher, while & indicates when both haplotype peaks are approximately of the same height.

https://doi.org/10.1371/journal.pone.0095010.s003

(DOC)

Acknowledgments

Special thanks to A. Kaliontzopoulou, A. Perera and A. Oliveira for their guidance in statistics and to M. D. Piulachs for laboratory support. Thanks to our colleagues from CIBIO, especially A. Perera, A. Kaliontzopoulou, F. Jorge and V. Gomes, who helped with the fieldwork and to the people and entities that made it possible to obtain samples from Parque Nacional Peneda-Gerês. Thanks also to the two anonymous reviewers and the assistant editor for their helpful comments on an earlier draft of this manuscript.

Author Contributions

Conceived and designed the experiments: JPM EGD DJH SC. Performed the experiments: JPM. Analyzed the data: JPM EGD. Contributed reagents/materials/analysis tools: JPM DJH SC. Wrote the paper: JPM EGD DJH SC.

References

1. Agnew P, Koella JC (1999) Life history interactions with environmental conditions in a host-parasite relationship and the parasite's mode of transmission. Evol Ecol 13: 67–89.
- View Article
- Google Scholar
2. Thomas F, Guégan J, Michalakis Y, Renaud F (2000) Parasites and host life-history traits: implications for community ecology and species co-existence. Int J Parasitol 30: 669–674.
- View Article
- Google Scholar
3. Poulin R (1999) The functional importance of parasites in animal communities: many roles at many levels? Int J Parasitol 29: 903–914.
- View Article
- Google Scholar
4. Hudson PJ, Greenman J (1998) Competition mediated by parasites: biological and theoretical progress. Trends Ecol Evol 13: 387–390.
- View Article
- Google Scholar
5. Hatcher MJ, Dick JT, Dunn AM (2006) How parasites affect interactions between competitors and predators. Ecol Lett 9: 1253–1271.
- View Article
- Google Scholar
6. Knowles SCL, Wood MJ, Alves R, Wilkin T, Bensch S, et al. (2011) Molecular epidemiology of malaria prevalence and parasitaemia in a wild bird population. Mol Ecol 20: 1062–1076.
- View Article
- Google Scholar
7. Poulin R (2006) Variation in infection parameters among populations within parasite species: intrinsic properties versus local factors. Int J Parasitol 36: 877–885.
- View Article
- Google Scholar
8. Tompkins DM, Dunn AM, Smith MJ, Telfer S (2011) Wildlife diseases: from individuals to ecosystems. J Anim Ecol 80: 19–38.
- View Article
- Google Scholar
9. Simberloff D (2010) The Biogeography of Host—Parasite Interactions. Morand S, Krasnov BR, editors. Oxford University Press. 288 p.
10. Klein SL (2004) Hormonal and immunological mechanisms mediating sex differences in parasite infection. Parasite Immunol 26: 247–264.
- View Article
- Google Scholar
11. Combes C (1996) Parasites, biodiversity and ecosystem stability. Biodivers Conserv 5: 953–962.
- View Article
- Google Scholar
12. Hawley DM, Altizer SM (2011) Disease ecology meets ecological immunology: understanding the links between organismal immunity and infection dynamics in natural populations. Funct Ecol 25: 48–60.
- View Article
- Google Scholar
13. Folstad I, Karter AJ (1992) Parasites, bright males, and the immunocompetence handicap. Am Nat 139: 603–622.
- View Article
- Google Scholar
14. Banoo S, Bell D, Bossuyt P, Herring A, Mabey D, et al. (2008) Evaluation of diagnostic tests for infectious diseases: general principles. Nat Rev Microbiol 5: S16–S28.
- View Article
- Google Scholar
15. Espy MJ, Uhl JR, Sloan LM, Buckwalter SP, Jones MF, et al. (2006) Real-Time PCR in Clinical Microbiology: Applications for Routine Laboratory Testing. Clin Microbiol Rev 19: 595–595.
- View Article
- Google Scholar
16. Gómez-Díaz E, Doherty Jr PF, Duneau D, McCoy KD (2010) Cryptic vector divergence masks vector-specific patterns of infection: an example from the marine cycle of Lyme borreliosis. Evol Appl 3: 391–401.
- View Article
- Google Scholar
17. Kelly PJ, Xu C, Lucas H, Loftis A, Abete J, et al. (2013) Ehrlichiosis, babesiosis, anaplasmosis and hepatozoonosis in dogs from St. Kitts, West Indies. PLoS One 8: e53450.
- View Article
- Google Scholar
18. Criado-Fornelio A, Buling A, Cunha-Filho NA, Ruas JL, Farias NAR, et al. (2007) Development and evaluation of a quantitative PCR assay for detection of Hepatozoon sp. Vet Parasitol 150: 352–356.
- View Article
- Google Scholar
19. Alvarez WA, Gibbons PM, Rivera S, Archer LL, Childress AL, et al. (2013) Development of a quantitative PCR for rapid and sensitive diagnosis of an intranuclear coccidian parasite in Testudines (TINC), and detection in the critically endangered Arakan forest turtle (Heosemys depressa). Vet Parasitol 193: 66–70.
- View Article
- Google Scholar
20. Li Y, Wang C, Allen KE, Little SE, Ahluwalia SK, et al. (2008) Diagnosis of canine Hepatozoon spp. infection by quantitative PCR. Vet Parasitol 157: 50–58.
- View Article
- Google Scholar
21. Perandin F, Manca N, Calderaro A, Piccolo G, Galati L, et al. (2004) Development of a Real-Time PCR Assay for Detection of Plasmodium falciparum, Plasmodium vivax, and Plasmodium ovale for Routine Clinical Diagnosis. J Clin Microbiol 42: 1214–1219.
- View Article
- Google Scholar
22. Mangold KA, Manson RU, Koay ESC, Stephens L, Regner M, et al. (2005) Real-time PCR for detection and identification of Plasmodium spp. J Clin Microbiol 43: 2435–2440.
- View Article
- Google Scholar
23. Grodio JL, Dhondt K V, O′Connell PH, Schat K (2008) Detection and quantification of Mycoplasma gallisepticum genome load in conjunctival samples of experimentally infected house finches (Carpodacus mexicanus) using real-time polymerase chain reaction. Avian Pathol 37: 385–391.
- View Article
- Google Scholar
24. Friedl TWP, Groscurth E (2011) A real-time PCR protocol for simple and fast quantification of blood parasite infections in evolutionary and ecological studies and some data on intensities of blood parasite infections in a subtropical weaverbird. J Ornithol 153: 239–247.
- View Article
- Google Scholar
25. Njabo KY, Cornel AJ, Bonneaud C, Toffelmier E, Sehgal RNM, et al. (2011) Nonspecific patterns of vector, host and avian malaria parasite associations in a central African rainforest. Mol Ecol 20: 1049–1061.
- View Article
- Google Scholar
26. Thomas F, Renaud F, Rousset F, Cezilly F, Meeus TD (1995) Differential Mortality of Two Closely Related Host Species Induced by One Parasite. Proc Biol Sci 260: 349–352.
- View Article
- Google Scholar
27. Poulin R (2011) The many roads to parasitism: a tale of convergence. Adv Parasitol 74: 1–40.
- View Article
- Google Scholar
28. Camargo A, Sinervo B, Sites JW (2010) Lizards as model organisms for linking phylogeographic and speciation studies. Mol Ecol 19: 3250–3270.
- View Article
- Google Scholar
29. Beldomenico PM, Begon M (2010) Disease spread, susceptibility and infection intensity: vicious circles? Trends Ecol Evol 25: 21–27.
- View Article
- Google Scholar
30. Bonneaud C, Balenger SL, Zhang J, Edwards S V, Hill GE (2012) Innate immunity and the evolution of resistance to an emerging infectious disease in a wild bird. Mol Ecol 21: 2628–2639.
- View Article
- Google Scholar
31. Turner AK, Begon M, Jackson J, Bradley JE, Paterson S (2011) Genetic diversity in cytokines associated with immune variation and resistance to multiple pathogens in a natural rodent population. PLoS Genet 7: e1002343.
- View Article
- Google Scholar
32. Allen HK, Donato J, Wang HH, Cloud-Hansen K, Davies J, et al. (2010) Call of the wild: antibiotic resistance genes in natural environments. Nat Rev Microbiol 8: 251–259.
- View Article
- Google Scholar
33. García-Ramírez A, Delgado-García JD, Foronda-Rodríguez P, Abreu-Acosta N (2005) Haematozoans, mites and body condition in the oceanic island lizard Gallotia atlantica (Peters and Doria, 1882) (Reptilia: Lacertidae). J Nat Hist 39: 1299–1305.
- View Article
- Google Scholar
34. Garrido M, Pérez-Mellado V (2013) Patterns of parasitism in insular lizards: effects of body size, condition and resource availability. Zoology 116: 106–112.
- View Article
- Google Scholar
35. Madsen T, Ujvari B, Olsson M (2005) Old pythons stay fit; effects of haematozoan infections on life history traits of a large tropical predator. Oecologia 142: 407–412.
- View Article
- Google Scholar
36. Brown GP, Shilton CM, Shine R (2006) Do parasites matter? Assessing the fitness consequences of haemogregarine infection in snakes. Can J Zool 84: 668–676.
- View Article
- Google Scholar
37. Amo L, López P, Martín J (2005) Prevalence and intensity of haemogregarine blood parasites and their mite vectors in the common wall lizard, Podarcis muralis. Parasitol Res 96: 378–381.
- View Article
- Google Scholar
38. Agnew P, C Koella J, Michalakis Y (2000) Host life history responses to parasitism. Microbes Infect 2: 891–896.
- View Article
- Google Scholar
39. Poulin R (1994) Meta-analysis of parasite-induced behavioural changes. Anim Behav 48: 137–146.
- View Article
- Google Scholar
40. Fenner AL, Godfrey SS, Michael Bull C (2011) Using social networks to deduce whether residents or dispersers spread parasites in a lizard population. J Anim Ecol 80: 835–843.
- View Article
- Google Scholar
41. Schmid-Hempel P (2003) Variation in immune defence as a question of evolutionary ecology. Proc Biol Sci 270: 357–366.
- View Article
- Google Scholar
42. Poulin R (1995) Phylogeny, Ecology, and the Richness of Parasite Communities in Vertebrates. Ecol Monogr 65: 283.
- View Article
- Google Scholar
43. Amo L, López P, Martín J (2004) Prevalence and intensity of haemogregarinid blood parasites in a population of the Iberian rock lizard, Lacerta monticola. Parasitol Res 94: 290–293.
- View Article
- Google Scholar
44. Poulin R (2005) Relative infection levels and taxonomic distances among the host species used by a parasite: insights into parasite specialization. Parasitology 130: 109–115.
- View Article
- Google Scholar
45. Morand S, Poulin R (2003) Phylogenies, the comparative method and parasite evolutionary ecology. Adv Parasitol 54: 281–302.
- View Article
- Google Scholar
46. Smith TG (1996) The genus Hepatozoon (Apicomplexa: Adeleina). J Parasitol 82: 565–585.
- View Article
- Google Scholar
47. Telford SR (2009) Hemoparasites of the Reptilia. CRC Press, Taylor and Francis Group, Boca Raton, Florida. 394 p.
48. Roca V, Galdón MA (2010) Haemogregarine blood parasites in the lizards Podarcis bocagei (Seoane) and P. carbonelli (Pérez-Mellado) (Sauria: Lacertidae) from NW Portugal. Syst Parasitol 75: 75–79.
- View Article
- Google Scholar
49. Tomé B, Maia JPMC, Harris DJ (2013) Molecular assessment of apicomplexan parasites in the snake Psammophis from north Africa: do multiple parasite lineages reflect the final vertebrate host diet? J Parasitol 99: 883–887.
- View Article
- Google Scholar
50. Maia JPMC, Perera A, Harris DJ (2012) Molecular survey and microscopic examination of Hepatozoon Miller, 1908 (Apicomplexa: Adeleorina) in lacertid lizards from the western Mediterranean. Folia Parasitol 59: 241–248.
- View Article
- Google Scholar
51. Garrido M, Pérez-Mellado V (2013) Prevalence and intensity of blood parasites in insular lizards. Zool Anzeiger - A J Comp Zool 252: 588–592.
- View Article
- Google Scholar
52. Wozniak EJ, Telford SR, McLaughlin GL (1994) Employment of the Polymerase Chain Reaction in the Molecular Differentiation of Reptilian Hemogregarines and Its Application to Preventative Zoological Medicine. J Zoo Wildl Med 25: 538–547.
- View Article
- Google Scholar
53. Wozniak EJ, Kazacos KR, Telford SR, McLaughlin GL (1996) Characterization of the clinical and anatomical pathological changes associated with Hepatozoon mocassini infections in unnatural reptilian hosts. Int J Parasitol 26: 141–146.
- View Article
- Google Scholar
54. Allen KE, Li Y, Kaltenboeck B, Johnson EM, Reichard MV, et al. (2008) Diversity of Hepatozoon species in naturally infected dogs in the southern United States. Vet Parasitol 154: 220–225.
- View Article
- Google Scholar
55. Baneth G (2011) Perspectives on canine and feline hepatozoonosis. Vet Parasitol 181: 3–11.
- View Article
- Google Scholar
56. Megía-Palma R, Martínez J, Merino S (2013) Phylogenetic analysis based on 18 S rRNA gene sequences of Schellackia parasites (Apicomplexa: Lankesterellidae) reveals their close relationship to the genus Eimeria. Parasitology 140: 1149–1157.
- View Article
- Google Scholar
57. Harris DJ, Maia JPMC, Perera A (2012) Molecular survey of Apicomplexa in Podarcis wall lizards detects Hepatozoon, Sarcocystis, and Eimeria species. J Parasitol 98: 592–597.
- View Article
- Google Scholar
58. Sá-Sousa P, Vicente L, Crespo E (2002) Morphological variability of Podarcis hispanica (Sauria: Lacertidae) in Portugal. Amphibia-Reptilia 23: 55–69.
- View Article
- Google Scholar
59. Sá-Sousa P, Harris DJ (2002) Podarcis carbonelli Pérez-Mellado, 1981 is a distinct species. Amphibia-Reptilia 23: 459–468.
- View Article
- Google Scholar
60. Pinho C, Harris DJ, Ferrand N (2008) Non-equilibrium estimates of gene flow inferred from nuclear genealogies suggest that Iberian and North African wall lizards (Podarcis spp.) are an assemblage of incipient species. BMC Evol Biol 8: 63.
- View Article
- Google Scholar
61. Harris DJ, Sá-Sousa P (2001) Species Distinction and Relationships of the Western Iberian Podarcis Lizards (Reptilia, Lacertidae) based on Morphology and Mitochondrial DNA sequences. Herpetol J 11: 129–136.
- View Article
- Google Scholar
62. Kaliontzopoulou A, Carretero MA, Llorente GA (2012) Morphology of the Podarcis wall lizards (Squamata: Lacertidae) from the Iberian Peninsula and North Africa: patterns of variation in a putative cryptic species complex. Zool J Linn Soc 164: 173–193.
- View Article
- Google Scholar
63. Kaliontzopoulou A, Carretero MA, Llorente GA (2008) Head shape allometry and proximate causes of head sexual dimorphism in Podarcis lizards: joining linear and geometric morphometrics. Biol J Linn Soc 93: 111–124.
- View Article
- Google Scholar
64. Margolis AL, Esch GW, Holmes JC, Kuris AM, Schad GA (1982) The Use of Ecological Terms in Parasitology (Report of an Ad Hoc Committee of the American Society of Parasitologists). J Parasitol 68: 131–133.
- View Article
- Google Scholar
65. Bush AO, Lafferty KD, Lotz JM, Shostak AW (1997) Parasitology meets ecology on its own terms: Margolis et al. revisited. J Parasitol 83: 575–583.
- View Article
- Google Scholar
66. Abramoff MD, Magalhães PJ, Ram SJ (2004) Image processing with ImageJ. Biophotonics Int 11: 36–42.
- View Article
- Google Scholar
67. Sambrook J, Fritsch EF, Maniatis T (1989) Molecular cloning: A laboratory manual. New York: Cold Spring Harbor Press. 545 p.
68. Cogswell FB, Bantar CE, Hughes TG, Gu Y, Philipp MT (1996) Host DNA can interfere with detection of Borrelia burgdorferi in skin biopsy specimens by PCR. J Clin Microbiol 34: 980–982.
- View Article
- Google Scholar
69. Ujvari B, Madsen T, Olsson M (2004) High prevalence of Hepatozoon spp. (Apicomplexa, Hepatozoidae) infection in water pythons (Liasis fuscus) from tropical Australia. J Parasitol 90: 670–672.
- View Article
- Google Scholar
70. Edgar RC (2004) MUSCLE: multiple sequence alignment with high accuracy and high throughput. Nucleic Acids Res 32: 1792–1797.
- View Article
- Google Scholar
71. Guindon S, Dufayard JF, Lefort V, Anisimova M, Hordijk W, et al. (2010) New algorithms and methods to estimate maximum-likelihood phylogenies: assessing the performance of PhyML 3.0. Syst Biol 59: 307–321.
- View Article
- Google Scholar
72. Felsenstein J (1985) Confidence Limits on Phylogenies: An Approach Using the Bootstrap. Evolution (N Y) 39: 783–791.
- View Article
- Google Scholar
73. Posada D (2008) jModelTest: phylogenetic model averaging. Mol Biol Evol 25: 1253–1256.
- View Article
- Google Scholar
74. Ronquist F, Huelsenbeck JP (2003) MrBayes 3: Bayesian phylogenetic inference under mixed models. Bioinformatics 19: 1572–1574.
- View Article
- Google Scholar
75. Rozen S, Skaletsky H (2000) Primer3 on the WWW for general users and for biologist programmers. Methods Mol Biol 132: 365–386.
- View Article
- Google Scholar
76. Ruijter JM, Ramakers C, Hoogaars WMH, Karlen Y, Bakker O, et al. (2009) Amplification efficiency: linking baseline and bias in the analysis of quantitative PCR data. Nucleic Acids Res 37: e45.
- View Article
- Google Scholar
77. Bolker BM, Brooks ME, Clark CJ, Geange SW, Poulsen JR, et al. (2009) Generalized linear mixed models: a practical guide for ecology and evolution. Trends Ecol Evol 24: 127–135.
- View Article
- Google Scholar
78. Whiteman NK, Matson KD, Bollmer JL, Parker PG (2006) Disease ecology in the Galápagos Hawk (Buteo galapagoensis): host genetic diversity, parasite load and natural antibodies. Proc Biol Sci 273: 797–804.
- View Article
- Google Scholar
79. Maia da Silva F, Marcili A, Ortiz PA, Epiphanio S, Campaner M, et al. (2010) Phylogenetic, morphological and behavioural analyses support host switching of Trypanosoma (Herpetosoma) lewisi from domestic rats to primates. Infect Genet Evol 10: 522–529.
- View Article
- Google Scholar
80. Perera A, Maia JPMC, Jorge F, Harris DJ (2013) Molecular screening of nematodes in lacertid lizards from the Iberian Peninsula and Balearic Islands using 18 S rRNA sequences. J Helminthol 87: 189–194.
- View Article
- Google Scholar
81. Tsangaras K, Greenwood AD (2012) Museums and disease: using tissue archive and museum samples to study pathogens. Ann Anat 194: 58–73.
- View Article
- Google Scholar
82. Altwegg M (1995) General problems associated with diagnostic applications of amplification methods. J Microbiol Methods 23: 21–30.
- View Article
- Google Scholar
83. Perkins SL, Keller AK (2001) Phylogeny of nuclear small subunit rRNA genes of hemogregarines amplified with specific primers. J Parasitol 87: 870–876.
- View Article
- Google Scholar
84. Bensch S, Pérez-Tris J, Waldenström J, Hellgren O (2004) Linkage between nuclear and mitochondrial DNA sequences in avian malaria parasites: multiple cases of cryptic speciation? Evolution 58: 1617–1621.
- View Article
- Google Scholar
85. Morrison DA (2009) Evolution of the Apicomplexa: where are we now? Trends Parasitol 25: 375–382.
- View Article
- Google Scholar
86. Jirků M, Jirků M, Oborník M, Lukes J, Modrý D (2009) A model for taxonomic work on homoxenous coccidia: redescription, host specificity, and molecular phylogeny of Eimeria ranae Dobell, 1909, with a review of anuran-host Eimeria (Apicomplexa: Eimeriorina). J Eukaryot Microbiol 56: 39–51.
- View Article
- Google Scholar
87. Wood MJ, Cosgrove CL, Wilkin T, Knowles SCL, Day KP, et al. (2007) Within-population variation in prevalence and lineage distribution of avian malaria in blue tits, Cyanistes caeruleus. Mol Ecol 16: 3263–3273.
- View Article
- Google Scholar
88. Eisen RJ, Wright NM (2001) Landscape features associated with infection by a malaria parasite (Plasmodium mexicanum) and the importance of multiple scale studies. Parasitology 122: 507–513.
- View Article
- Google Scholar
89. Pérez-Tris J, Hellgren O, Križanauskienè A, Waldenström J, Secondi J, et al. (2007) Within-Host Speciation of Malaria Parasites. PLoS One 2: 7.
- View Article
- Google Scholar
90. Vardo AM, Schall JJ (2007) Clonal diversity of a lizard malaria parasite, Plasmodium mexicanum, in its vertebrate host, the western fence lizard: role of variation in transmission intensity over time and space. Mol Ecol 16: 2712–2720.
- View Article
- Google Scholar
91. Molnár O, Bajer K, Mészáros B, Török J, Herczeg G (2013) Negative correlation between nuptial throat colour and blood parasite load in male European green lizards supports the Hamilton-Zuk hypothesis. Naturwissenschaften 100: 551–558.
- View Article
- Google Scholar
92. Halliday T, Verrell P (1988) Body size and age in amphibians and reptiles. J Herpetol 22: 253–265.
- View Article
- Google Scholar
93. Pough FH, Andrews RM, Cadle JE, Crump ML, Savitzky AH, et al.. (2004) Herpetology. Third. New York: Prentice Hall. 726 p.
94. Palacios MG, Winkler DW, Klasing KC, Hasselquist D, Vleck CM (2011) Consequences of immune system aging in nature: a study of immunosenescence costs in free-living Tree Swallows. Ecology 92: 952–966.
- View Article
- Google Scholar
95. Madsen T, Ujvari B (2006) MHC class I variation associates with parasite resistance and longevity in tropical pythons. J Evol Biol 19: 1973–1978.
- View Article
- Google Scholar
96. Godfrey SS, Nelson NJ, Bull CM (2011) Ecology and dynamics of the blood parasite, Hepatozoon tuatarae (Apicomplexa), in tuatara (Sphenodon punctatus) on Stephens Island, New Zealand. J Wildl Dis 47: 126–139.
- View Article
- Google Scholar
97. Amo L, Fargallo JA, Martínez-Padilla J, Millán J, López P, et al. (2005) Prevalence and intensity of blood and intestinal parasites in a field population of a Mediterranean lizard, Lacerta lepida. Parasitol Res 96: 413–417.
- View Article
- Google Scholar
98. Telfer S, Lambin X, Birtles R, Beldomenico P, Burthe S, et al. (2010) Species interactions in a parasite community drive infection risk in a wildlife population. Science 330: 243–246.
- View Article
- Google Scholar
99. Brunham RC, Plummer FA, Stephens RS (1993) Bacterial antigenic variation, host immune response, and pathogen-host coevolution. Infect Immun 61: 2273–2276.
- View Article
- Google Scholar
100. Martínez-de la Puente J, Martínez J, Rivero-de Aguilar J, Herrero J, Merino S (2011) On the specificity of avian blood parasites: revealing specific and generalist relationships between haemosporidians and biting midges. Mol Ecol 20: 3275–3287.
- View Article
- Google Scholar
101. Ishtiaq F, Guillaumot L, Clegg SM, Phillimore AB, Black RA, et al. (2008) Avian haematozoan parasites and their associations with mosquitoes across Southwest Pacific Islands. Mol Ecol 17: 4545–4555.
- View Article
- Google Scholar
102. Hellgren O, Krizanauskiene A, Valkiūnas G, Bensch S (2007) Diversity and phylogeny of mitochondrial cytochrome B lineages from six morphospecies of avian Haemoproteus (Haemosporida: Haemoproteidae). J Parasitol 93: 889–896.
- View Article
- Google Scholar
103. Perkins SL (2001) Phylogeography of Caribbean lizard malaria: tracing the history of vector-borne parasites. J Evol Biol 14: 34–45.
- View Article
- Google Scholar
104. Reardon JT, Norbury G (2004) Ectoparasite and hemoparasite infection in a diverse temperate lizard assemblage at Macraes Flat, South Island, New Zealand. J Parasitol 90: 1274–1278.
- View Article
- Google Scholar
105. Lee KA (2006) Linking immune defenses and life history at the levels of the individual and the species. Integr Comp Biol 46: 1000–1015.
- View Article
- Google Scholar
106. Sacchi R, Scali S, Cavirani V, Pupin F, Pellitteri-Rosa D, et al. (2011) Leukocyte differential counts and morphology from twelve European lizards. Ital J Zool 78: 418–426.
- View Article
- Google Scholar
107. Figuerola J, Munoz E, Gutierrez R, Ferrer D (1999) Blood parasites, leucocytes and plumage brightness in the Cirl Bunting, Emberiza cirlus. Funct Ecol 13: 594–601.
- View Article
- Google Scholar
108. Lindström KM, Foufopoulos J, Pärn H, Wikelski M (2004) Immunological investments reflect parasite abundance in island populations of Darwin's finches. Proc Biol Sci 271: 1513–1519.
- View Article
- Google Scholar
109. Jacquin L, Lenouvel P, Haussy C, Ducatez S, Gasparini J (2011) Melanin-based coloration is related to parasite intensity and cellular immune response in an urban free living bird: the feral pigeon Columba livia. J Avian Biol 42: 11–15.
- View Article
- Google Scholar
110. Westerdahl H, Stjernman M, Råberg L, Lannefors M, Nilsson J-Å (2013) MHC-I affects infection intensity but not infection status with a frequent avian malaria parasite in blue tits. PLoS One 8: e72647.
- View Article
- Google Scholar
111. Ujvari B, Madsen T (2005) Age, parasites, and condition affect humoral immune response in tropical pythons. Behav Ecol 17: 20–24.
- View Article
- Google Scholar
112. Salkeld DJ, Schwarzkopf L (2005) Epizootiology of blood parasites in an Australian lizard: a mark-recapture study of a natural population. Int J Parasitol 35: 11–18.
- View Article
- Google Scholar
113. Salvador A, Veiga JP, Martin J, Lopez P, Abelenda M, et al. (1996) The cost of producing a sexual signal: testosterone increases the susceptibility of male lizards to ectoparasitic infestation. Behav Ecol 7: 145–150.
- View Article
- Google Scholar
114. Restif O, Amos W (2010) The evolution of sex-specific immune defences. Proc Biol Sci 277: 2247–2255.
- View Article
- Google Scholar
115. Lachish S, Knowles SCL, Alves R, Sepil I, Davies A, et al. (2013) Spatial determinants of infection risk in a multi-species avian malaria system. Ecography 36: 587–598.
- View Article
- Google Scholar
116. Møller AP, Merino S, Soler JJ, Antonov A, Badás EP, et al. (2013) Assessing the effects of climate on host-parasite interactions: a comparative study of European birds and their parasites. PLoS One 8: e82886.
- View Article
- Google Scholar
117. Ferraguti M, Martínez-de la Puente J, Muñoz J, Roiz D, Ruiz S, et al. (2013) Avian Plasmodium in Culex and Ochlerotatus Mosquitoes from Southern Spain: Effects of Season and Host-Feeding Source on Parasite Dynamics. PLoS One 8: e66237.
- View Article
- Google Scholar
118. Altizer S, Dobson A, Hosseini P, Hudson P, Pascual M, et al. (2006) Seasonality and the dynamics of infectious diseases. Ecol Lett 9: 467–484.
- View Article
- Google Scholar
119. Uchii K, Telschow A, Minamoto T, Yamanaka H, Honjo MN, et al. (2011) Transmission dynamics of an emerging infectious disease in wildlife through host reproductive cycles. ISME J 5: 244–251.
- View Article
- Google Scholar
120. Huyghe K, Van Oystaeyen A, Pasmans F, Tadić Z, Vanhooydonck B, et al. (2010) Seasonal changes in parasite load and a cellular immune response in a colour polymorphic lizard. Oecologia 163: 867–874.
- View Article
- Google Scholar
121. Møller AP, Erritzøe J, Saino N (2003) Seasonal changes in immune response and parasite impact on hosts. Am Nat 161: 657–671.
- View Article
- Google Scholar
122. Maia JPMC, Harris DJ, Perera A (2011) Molecular survey of Hepatozoon species in lizards from North Africa. J Parasitol 97: 513–517.
- View Article
- Google Scholar

[ref1] 1. Agnew P, Koella JC (1999) Life history interactions with environmental conditions in a host-parasite relationship and the parasite's mode of transmission. Evol Ecol 13: 67–89.
View Article
Google Scholar

[2] View Article

[3] Google Scholar

[ref2] 2. Thomas F, Guégan J, Michalakis Y, Renaud F (2000) Parasites and host life-history traits: implications for community ecology and species co-existence. Int J Parasitol 30: 669–674.
View Article
Google Scholar

[5] View Article

[6] Google Scholar

[ref3] 3. Poulin R (1999) The functional importance of parasites in animal communities: many roles at many levels? Int J Parasitol 29: 903–914.
View Article
Google Scholar

[8] View Article

[9] Google Scholar

[ref4] 4. Hudson PJ, Greenman J (1998) Competition mediated by parasites: biological and theoretical progress. Trends Ecol Evol 13: 387–390.
View Article
Google Scholar

[11] View Article

[12] Google Scholar

[ref5] 5. Hatcher MJ, Dick JT, Dunn AM (2006) How parasites affect interactions between competitors and predators. Ecol Lett 9: 1253–1271.
View Article
Google Scholar

[14] View Article

[15] Google Scholar

[ref6] 6. Knowles SCL, Wood MJ, Alves R, Wilkin T, Bensch S, et al. (2011) Molecular epidemiology of malaria prevalence and parasitaemia in a wild bird population. Mol Ecol 20: 1062–1076.
View Article
Google Scholar

[17] View Article

[18] Google Scholar

[ref7] 7. Poulin R (2006) Variation in infection parameters among populations within parasite species: intrinsic properties versus local factors. Int J Parasitol 36: 877–885.
View Article
Google Scholar

[20] View Article

[21] Google Scholar

[ref8] 8. Tompkins DM, Dunn AM, Smith MJ, Telfer S (2011) Wildlife diseases: from individuals to ecosystems. J Anim Ecol 80: 19–38.
View Article
Google Scholar

[23] View Article

[24] Google Scholar

[ref9] 9. Simberloff D (2010) The Biogeography of Host—Parasite Interactions. Morand S, Krasnov BR, editors. Oxford University Press. 288 p.

[ref10] 10. Klein SL (2004) Hormonal and immunological mechanisms mediating sex differences in parasite infection. Parasite Immunol 26: 247–264.
View Article
Google Scholar

[27] View Article

[28] Google Scholar

[ref11] 11. Combes C (1996) Parasites, biodiversity and ecosystem stability. Biodivers Conserv 5: 953–962.
View Article
Google Scholar

[30] View Article

[31] Google Scholar

[ref12] 12. Hawley DM, Altizer SM (2011) Disease ecology meets ecological immunology: understanding the links between organismal immunity and infection dynamics in natural populations. Funct Ecol 25: 48–60.
View Article
Google Scholar

[33] View Article

[34] Google Scholar

[ref13] 13. Folstad I, Karter AJ (1992) Parasites, bright males, and the immunocompetence handicap. Am Nat 139: 603–622.
View Article
Google Scholar

[36] View Article

[37] Google Scholar

[ref14] 14. Banoo S, Bell D, Bossuyt P, Herring A, Mabey D, et al. (2008) Evaluation of diagnostic tests for infectious diseases: general principles. Nat Rev Microbiol 5: S16–S28.
View Article
Google Scholar

[39] View Article

[40] Google Scholar

[ref15] 15. Espy MJ, Uhl JR, Sloan LM, Buckwalter SP, Jones MF, et al. (2006) Real-Time PCR in Clinical Microbiology: Applications for Routine Laboratory Testing. Clin Microbiol Rev 19: 595–595.
View Article
Google Scholar

[42] View Article

[43] Google Scholar

[ref16] 16. Gómez-Díaz E, Doherty Jr PF, Duneau D, McCoy KD (2010) Cryptic vector divergence masks vector-specific patterns of infection: an example from the marine cycle of Lyme borreliosis. Evol Appl 3: 391–401.
View Article
Google Scholar

[45] View Article

[46] Google Scholar

[ref17] 17. Kelly PJ, Xu C, Lucas H, Loftis A, Abete J, et al. (2013) Ehrlichiosis, babesiosis, anaplasmosis and hepatozoonosis in dogs from St. Kitts, West Indies. PLoS One 8: e53450.
View Article
Google Scholar

[48] View Article

[49] Google Scholar

[ref18] 18. Criado-Fornelio A, Buling A, Cunha-Filho NA, Ruas JL, Farias NAR, et al. (2007) Development and evaluation of a quantitative PCR assay for detection of Hepatozoon sp. Vet Parasitol 150: 352–356.
View Article
Google Scholar

[51] View Article

[52] Google Scholar

[ref19] 19. Alvarez WA, Gibbons PM, Rivera S, Archer LL, Childress AL, et al. (2013) Development of a quantitative PCR for rapid and sensitive diagnosis of an intranuclear coccidian parasite in Testudines (TINC), and detection in the critically endangered Arakan forest turtle (Heosemys depressa). Vet Parasitol 193: 66–70.
View Article
Google Scholar

[54] View Article

[55] Google Scholar

[ref20] 20. Li Y, Wang C, Allen KE, Little SE, Ahluwalia SK, et al. (2008) Diagnosis of canine Hepatozoon spp. infection by quantitative PCR. Vet Parasitol 157: 50–58.
View Article
Google Scholar

[57] View Article

[58] Google Scholar

[ref21] 21. Perandin F, Manca N, Calderaro A, Piccolo G, Galati L, et al. (2004) Development of a Real-Time PCR Assay for Detection of Plasmodium falciparum, Plasmodium vivax, and Plasmodium ovale for Routine Clinical Diagnosis. J Clin Microbiol 42: 1214–1219.
View Article
Google Scholar

[60] View Article

[61] Google Scholar

[ref22] 22. Mangold KA, Manson RU, Koay ESC, Stephens L, Regner M, et al. (2005) Real-time PCR for detection and identification of Plasmodium spp. J Clin Microbiol 43: 2435–2440.
View Article
Google Scholar

[63] View Article

[64] Google Scholar

[ref23] 23. Grodio JL, Dhondt K V, O′Connell PH, Schat K (2008) Detection and quantification of Mycoplasma gallisepticum genome load in conjunctival samples of experimentally infected house finches (Carpodacus mexicanus) using real-time polymerase chain reaction. Avian Pathol 37: 385–391.
View Article
Google Scholar

[66] View Article

[67] Google Scholar

[ref24] 24. Friedl TWP, Groscurth E (2011) A real-time PCR protocol for simple and fast quantification of blood parasite infections in evolutionary and ecological studies and some data on intensities of blood parasite infections in a subtropical weaverbird. J Ornithol 153: 239–247.
View Article
Google Scholar

[69] View Article

[70] Google Scholar

[ref25] 25. Njabo KY, Cornel AJ, Bonneaud C, Toffelmier E, Sehgal RNM, et al. (2011) Nonspecific patterns of vector, host and avian malaria parasite associations in a central African rainforest. Mol Ecol 20: 1049–1061.
View Article
Google Scholar

[72] View Article

[73] Google Scholar

[ref26] 26. Thomas F, Renaud F, Rousset F, Cezilly F, Meeus TD (1995) Differential Mortality of Two Closely Related Host Species Induced by One Parasite. Proc Biol Sci 260: 349–352.
View Article
Google Scholar

[75] View Article

[76] Google Scholar

[ref27] 27. Poulin R (2011) The many roads to parasitism: a tale of convergence. Adv Parasitol 74: 1–40.
View Article
Google Scholar

[78] View Article

[79] Google Scholar

[ref28] 28. Camargo A, Sinervo B, Sites JW (2010) Lizards as model organisms for linking phylogeographic and speciation studies. Mol Ecol 19: 3250–3270.
View Article
Google Scholar

[81] View Article

[82] Google Scholar

[ref29] 29. Beldomenico PM, Begon M (2010) Disease spread, susceptibility and infection intensity: vicious circles? Trends Ecol Evol 25: 21–27.
View Article
Google Scholar

[84] View Article

[85] Google Scholar

[ref30] 30. Bonneaud C, Balenger SL, Zhang J, Edwards S V, Hill GE (2012) Innate immunity and the evolution of resistance to an emerging infectious disease in a wild bird. Mol Ecol 21: 2628–2639.
View Article
Google Scholar

[87] View Article

[88] Google Scholar

[ref31] 31. Turner AK, Begon M, Jackson J, Bradley JE, Paterson S (2011) Genetic diversity in cytokines associated with immune variation and resistance to multiple pathogens in a natural rodent population. PLoS Genet 7: e1002343.
View Article
Google Scholar

[90] View Article

[91] Google Scholar

[ref32] 32. Allen HK, Donato J, Wang HH, Cloud-Hansen K, Davies J, et al. (2010) Call of the wild: antibiotic resistance genes in natural environments. Nat Rev Microbiol 8: 251–259.
View Article
Google Scholar

[93] View Article

[94] Google Scholar

[ref33] 33. García-Ramírez A, Delgado-García JD, Foronda-Rodríguez P, Abreu-Acosta N (2005) Haematozoans, mites and body condition in the oceanic island lizard Gallotia atlantica (Peters and Doria, 1882) (Reptilia: Lacertidae). J Nat Hist 39: 1299–1305.
View Article
Google Scholar

[96] View Article

[97] Google Scholar

[ref34] 34. Garrido M, Pérez-Mellado V (2013) Patterns of parasitism in insular lizards: effects of body size, condition and resource availability. Zoology 116: 106–112.
View Article
Google Scholar

[99] View Article

[100] Google Scholar

[ref35] 35. Madsen T, Ujvari B, Olsson M (2005) Old pythons stay fit; effects of haematozoan infections on life history traits of a large tropical predator. Oecologia 142: 407–412.
View Article
Google Scholar

[102] View Article

[103] Google Scholar

[ref36] 36. Brown GP, Shilton CM, Shine R (2006) Do parasites matter? Assessing the fitness consequences of haemogregarine infection in snakes. Can J Zool 84: 668–676.
View Article
Google Scholar

[105] View Article

[106] Google Scholar

[ref37] 37. Amo L, López P, Martín J (2005) Prevalence and intensity of haemogregarine blood parasites and their mite vectors in the common wall lizard, Podarcis muralis. Parasitol Res 96: 378–381.
View Article
Google Scholar

[108] View Article

[109] Google Scholar

[ref38] 38. Agnew P, C Koella J, Michalakis Y (2000) Host life history responses to parasitism. Microbes Infect 2: 891–896.
View Article
Google Scholar

[111] View Article

[112] Google Scholar

[ref39] 39. Poulin R (1994) Meta-analysis of parasite-induced behavioural changes. Anim Behav 48: 137–146.
View Article
Google Scholar

[114] View Article

[115] Google Scholar

[ref40] 40. Fenner AL, Godfrey SS, Michael Bull C (2011) Using social networks to deduce whether residents or dispersers spread parasites in a lizard population. J Anim Ecol 80: 835–843.
View Article
Google Scholar

[117] View Article

[118] Google Scholar

[ref41] 41. Schmid-Hempel P (2003) Variation in immune defence as a question of evolutionary ecology. Proc Biol Sci 270: 357–366.
View Article
Google Scholar

[120] View Article

[121] Google Scholar

[ref42] 42. Poulin R (1995) Phylogeny, Ecology, and the Richness of Parasite Communities in Vertebrates. Ecol Monogr 65: 283.
View Article
Google Scholar

[123] View Article

[124] Google Scholar

[ref43] 43. Amo L, López P, Martín J (2004) Prevalence and intensity of haemogregarinid blood parasites in a population of the Iberian rock lizard, Lacerta monticola. Parasitol Res 94: 290–293.
View Article
Google Scholar

[126] View Article

[127] Google Scholar

[ref44] 44. Poulin R (2005) Relative infection levels and taxonomic distances among the host species used by a parasite: insights into parasite specialization. Parasitology 130: 109–115.
View Article
Google Scholar

[129] View Article

[130] Google Scholar

[ref45] 45. Morand S, Poulin R (2003) Phylogenies, the comparative method and parasite evolutionary ecology. Adv Parasitol 54: 281–302.
View Article
Google Scholar

[132] View Article

[133] Google Scholar

[ref46] 46. Smith TG (1996) The genus Hepatozoon (Apicomplexa: Adeleina). J Parasitol 82: 565–585.
View Article
Google Scholar

[135] View Article

[136] Google Scholar

[ref47] 47. Telford SR (2009) Hemoparasites of the Reptilia. CRC Press, Taylor and Francis Group, Boca Raton, Florida. 394 p.

[ref48] 48. Roca V, Galdón MA (2010) Haemogregarine blood parasites in the lizards Podarcis bocagei (Seoane) and P. carbonelli (Pérez-Mellado) (Sauria: Lacertidae) from NW Portugal. Syst Parasitol 75: 75–79.
View Article
Google Scholar

[139] View Article

[140] Google Scholar

[ref49] 49. Tomé B, Maia JPMC, Harris DJ (2013) Molecular assessment of apicomplexan parasites in the snake Psammophis from north Africa: do multiple parasite lineages reflect the final vertebrate host diet? J Parasitol 99: 883–887.
View Article
Google Scholar

[142] View Article

[143] Google Scholar

[ref50] 50. Maia JPMC, Perera A, Harris DJ (2012) Molecular survey and microscopic examination of Hepatozoon Miller, 1908 (Apicomplexa: Adeleorina) in lacertid lizards from the western Mediterranean. Folia Parasitol 59: 241–248.
View Article
Google Scholar

[145] View Article

[146] Google Scholar

[ref51] 51. Garrido M, Pérez-Mellado V (2013) Prevalence and intensity of blood parasites in insular lizards. Zool Anzeiger - A J Comp Zool 252: 588–592.
View Article
Google Scholar

[148] View Article

[149] Google Scholar

[ref52] 52. Wozniak EJ, Telford SR, McLaughlin GL (1994) Employment of the Polymerase Chain Reaction in the Molecular Differentiation of Reptilian Hemogregarines and Its Application to Preventative Zoological Medicine. J Zoo Wildl Med 25: 538–547.
View Article
Google Scholar

[151] View Article

[152] Google Scholar

[ref53] 53. Wozniak EJ, Kazacos KR, Telford SR, McLaughlin GL (1996) Characterization of the clinical and anatomical pathological changes associated with Hepatozoon mocassini infections in unnatural reptilian hosts. Int J Parasitol 26: 141–146.
View Article
Google Scholar

[154] View Article

[155] Google Scholar

[ref54] 54. Allen KE, Li Y, Kaltenboeck B, Johnson EM, Reichard MV, et al. (2008) Diversity of Hepatozoon species in naturally infected dogs in the southern United States. Vet Parasitol 154: 220–225.
View Article
Google Scholar

[157] View Article

[158] Google Scholar

[ref55] 55. Baneth G (2011) Perspectives on canine and feline hepatozoonosis. Vet Parasitol 181: 3–11.
View Article
Google Scholar

[160] View Article

[161] Google Scholar

[ref56] 56. Megía-Palma R, Martínez J, Merino S (2013) Phylogenetic analysis based on 18 S rRNA gene sequences of Schellackia parasites (Apicomplexa: Lankesterellidae) reveals their close relationship to the genus Eimeria. Parasitology 140: 1149–1157.
View Article
Google Scholar

[163] View Article

[164] Google Scholar

[ref57] 57. Harris DJ, Maia JPMC, Perera A (2012) Molecular survey of Apicomplexa in Podarcis wall lizards detects Hepatozoon, Sarcocystis, and Eimeria species. J Parasitol 98: 592–597.
View Article
Google Scholar

[166] View Article

[167] Google Scholar

[ref58] 58. Sá-Sousa P, Vicente L, Crespo E (2002) Morphological variability of Podarcis hispanica (Sauria: Lacertidae) in Portugal. Amphibia-Reptilia 23: 55–69.
View Article
Google Scholar

[169] View Article

[170] Google Scholar

[ref59] 59. Sá-Sousa P, Harris DJ (2002) Podarcis carbonelli Pérez-Mellado, 1981 is a distinct species. Amphibia-Reptilia 23: 459–468.
View Article
Google Scholar

[172] View Article

[173] Google Scholar

[ref60] 60. Pinho C, Harris DJ, Ferrand N (2008) Non-equilibrium estimates of gene flow inferred from nuclear genealogies suggest that Iberian and North African wall lizards (Podarcis spp.) are an assemblage of incipient species. BMC Evol Biol 8: 63.
View Article
Google Scholar

[175] View Article

[176] Google Scholar

[ref61] 61. Harris DJ, Sá-Sousa P (2001) Species Distinction and Relationships of the Western Iberian Podarcis Lizards (Reptilia, Lacertidae) based on Morphology and Mitochondrial DNA sequences. Herpetol J 11: 129–136.
View Article
Google Scholar

[178] View Article

[179] Google Scholar

[ref62] 62. Kaliontzopoulou A, Carretero MA, Llorente GA (2012) Morphology of the Podarcis wall lizards (Squamata: Lacertidae) from the Iberian Peninsula and North Africa: patterns of variation in a putative cryptic species complex. Zool J Linn Soc 164: 173–193.
View Article
Google Scholar

[181] View Article

[182] Google Scholar

[ref63] 63. Kaliontzopoulou A, Carretero MA, Llorente GA (2008) Head shape allometry and proximate causes of head sexual dimorphism in Podarcis lizards: joining linear and geometric morphometrics. Biol J Linn Soc 93: 111–124.
View Article
Google Scholar

[184] View Article

[185] Google Scholar

[ref64] 64. Margolis AL, Esch GW, Holmes JC, Kuris AM, Schad GA (1982) The Use of Ecological Terms in Parasitology (Report of an Ad Hoc Committee of the American Society of Parasitologists). J Parasitol 68: 131–133.
View Article
Google Scholar

[187] View Article

[188] Google Scholar

[ref65] 65. Bush AO, Lafferty KD, Lotz JM, Shostak AW (1997) Parasitology meets ecology on its own terms: Margolis et al. revisited. J Parasitol 83: 575–583.
View Article
Google Scholar

[190] View Article

[191] Google Scholar

[ref66] 66. Abramoff MD, Magalhães PJ, Ram SJ (2004) Image processing with ImageJ. Biophotonics Int 11: 36–42.
View Article
Google Scholar

[193] View Article

[194] Google Scholar

[ref67] 67. Sambrook J, Fritsch EF, Maniatis T (1989) Molecular cloning: A laboratory manual. New York: Cold Spring Harbor Press. 545 p.

[ref68] 68. Cogswell FB, Bantar CE, Hughes TG, Gu Y, Philipp MT (1996) Host DNA can interfere with detection of Borrelia burgdorferi in skin biopsy specimens by PCR. J Clin Microbiol 34: 980–982.
View Article
Google Scholar

[197] View Article

[198] Google Scholar

[ref69] 69. Ujvari B, Madsen T, Olsson M (2004) High prevalence of Hepatozoon spp. (Apicomplexa, Hepatozoidae) infection in water pythons (Liasis fuscus) from tropical Australia. J Parasitol 90: 670–672.
View Article
Google Scholar

[200] View Article

[201] Google Scholar

[ref70] 70. Edgar RC (2004) MUSCLE: multiple sequence alignment with high accuracy and high throughput. Nucleic Acids Res 32: 1792–1797.
View Article
Google Scholar

[203] View Article

[204] Google Scholar

[ref71] 71. Guindon S, Dufayard JF, Lefort V, Anisimova M, Hordijk W, et al. (2010) New algorithms and methods to estimate maximum-likelihood phylogenies: assessing the performance of PhyML 3.0. Syst Biol 59: 307–321.
View Article
Google Scholar

[206] View Article

[207] Google Scholar

[ref72] 72. Felsenstein J (1985) Confidence Limits on Phylogenies: An Approach Using the Bootstrap. Evolution (N Y) 39: 783–791.
View Article
Google Scholar

[209] View Article

[210] Google Scholar

[ref73] 73. Posada D (2008) jModelTest: phylogenetic model averaging. Mol Biol Evol 25: 1253–1256.
View Article
Google Scholar

[212] View Article

[213] Google Scholar

[ref74] 74. Ronquist F, Huelsenbeck JP (2003) MrBayes 3: Bayesian phylogenetic inference under mixed models. Bioinformatics 19: 1572–1574.
View Article
Google Scholar

[215] View Article

[216] Google Scholar

[ref75] 75. Rozen S, Skaletsky H (2000) Primer3 on the WWW for general users and for biologist programmers. Methods Mol Biol 132: 365–386.
View Article
Google Scholar

[218] View Article

[219] Google Scholar

[ref76] 76. Ruijter JM, Ramakers C, Hoogaars WMH, Karlen Y, Bakker O, et al. (2009) Amplification efficiency: linking baseline and bias in the analysis of quantitative PCR data. Nucleic Acids Res 37: e45.
View Article
Google Scholar

[221] View Article

[222] Google Scholar

[ref77] 77. Bolker BM, Brooks ME, Clark CJ, Geange SW, Poulsen JR, et al. (2009) Generalized linear mixed models: a practical guide for ecology and evolution. Trends Ecol Evol 24: 127–135.
View Article
Google Scholar

[224] View Article

[225] Google Scholar

[ref78] 78. Whiteman NK, Matson KD, Bollmer JL, Parker PG (2006) Disease ecology in the Galápagos Hawk (Buteo galapagoensis): host genetic diversity, parasite load and natural antibodies. Proc Biol Sci 273: 797–804.
View Article
Google Scholar

[227] View Article

[228] Google Scholar

[ref79] 79. Maia da Silva F, Marcili A, Ortiz PA, Epiphanio S, Campaner M, et al. (2010) Phylogenetic, morphological and behavioural analyses support host switching of Trypanosoma (Herpetosoma) lewisi from domestic rats to primates. Infect Genet Evol 10: 522–529.
View Article
Google Scholar

[230] View Article

[231] Google Scholar

[ref80] 80. Perera A, Maia JPMC, Jorge F, Harris DJ (2013) Molecular screening of nematodes in lacertid lizards from the Iberian Peninsula and Balearic Islands using 18 S rRNA sequences. J Helminthol 87: 189–194.
View Article
Google Scholar

[233] View Article

[234] Google Scholar

[ref81] 81. Tsangaras K, Greenwood AD (2012) Museums and disease: using tissue archive and museum samples to study pathogens. Ann Anat 194: 58–73.
View Article
Google Scholar

[236] View Article

[237] Google Scholar

[ref82] 82. Altwegg M (1995) General problems associated with diagnostic applications of amplification methods. J Microbiol Methods 23: 21–30.
View Article
Google Scholar

[239] View Article

[240] Google Scholar

[ref83] 83. Perkins SL, Keller AK (2001) Phylogeny of nuclear small subunit rRNA genes of hemogregarines amplified with specific primers. J Parasitol 87: 870–876.
View Article
Google Scholar

[242] View Article

[243] Google Scholar

[ref84] 84. Bensch S, Pérez-Tris J, Waldenström J, Hellgren O (2004) Linkage between nuclear and mitochondrial DNA sequences in avian malaria parasites: multiple cases of cryptic speciation? Evolution 58: 1617–1621.
View Article
Google Scholar

[245] View Article

[246] Google Scholar

[ref85] 85. Morrison DA (2009) Evolution of the Apicomplexa: where are we now? Trends Parasitol 25: 375–382.
View Article
Google Scholar

[248] View Article

[249] Google Scholar

[ref86] 86. Jirků M, Jirků M, Oborník M, Lukes J, Modrý D (2009) A model for taxonomic work on homoxenous coccidia: redescription, host specificity, and molecular phylogeny of Eimeria ranae Dobell, 1909, with a review of anuran-host Eimeria (Apicomplexa: Eimeriorina). J Eukaryot Microbiol 56: 39–51.
View Article
Google Scholar

[251] View Article

[252] Google Scholar

[ref87] 87. Wood MJ, Cosgrove CL, Wilkin T, Knowles SCL, Day KP, et al. (2007) Within-population variation in prevalence and lineage distribution of avian malaria in blue tits, Cyanistes caeruleus. Mol Ecol 16: 3263–3273.
View Article
Google Scholar

[254] View Article

[255] Google Scholar

[ref88] 88. Eisen RJ, Wright NM (2001) Landscape features associated with infection by a malaria parasite (Plasmodium mexicanum) and the importance of multiple scale studies. Parasitology 122: 507–513.
View Article
Google Scholar

[257] View Article

[258] Google Scholar

[ref89] 89. Pérez-Tris J, Hellgren O, Križanauskienè A, Waldenström J, Secondi J, et al. (2007) Within-Host Speciation of Malaria Parasites. PLoS One 2: 7.
View Article
Google Scholar

[260] View Article

[261] Google Scholar

[ref90] 90. Vardo AM, Schall JJ (2007) Clonal diversity of a lizard malaria parasite, Plasmodium mexicanum, in its vertebrate host, the western fence lizard: role of variation in transmission intensity over time and space. Mol Ecol 16: 2712–2720.
View Article
Google Scholar

[263] View Article

[264] Google Scholar

[ref91] 91. Molnár O, Bajer K, Mészáros B, Török J, Herczeg G (2013) Negative correlation between nuptial throat colour and blood parasite load in male European green lizards supports the Hamilton-Zuk hypothesis. Naturwissenschaften 100: 551–558.
View Article
Google Scholar

[266] View Article

[267] Google Scholar

[ref92] 92. Halliday T, Verrell P (1988) Body size and age in amphibians and reptiles. J Herpetol 22: 253–265.
View Article
Google Scholar

[269] View Article

[270] Google Scholar

[ref93] 93. Pough FH, Andrews RM, Cadle JE, Crump ML, Savitzky AH, et al.. (2004) Herpetology. Third. New York: Prentice Hall. 726 p.

[ref94] 94. Palacios MG, Winkler DW, Klasing KC, Hasselquist D, Vleck CM (2011) Consequences of immune system aging in nature: a study of immunosenescence costs in free-living Tree Swallows. Ecology 92: 952–966.
View Article
Google Scholar

[273] View Article

[274] Google Scholar

[ref95] 95. Madsen T, Ujvari B (2006) MHC class I variation associates with parasite resistance and longevity in tropical pythons. J Evol Biol 19: 1973–1978.
View Article
Google Scholar

[276] View Article

[277] Google Scholar

[ref96] 96. Godfrey SS, Nelson NJ, Bull CM (2011) Ecology and dynamics of the blood parasite, Hepatozoon tuatarae (Apicomplexa), in tuatara (Sphenodon punctatus) on Stephens Island, New Zealand. J Wildl Dis 47: 126–139.
View Article
Google Scholar

[279] View Article

[280] Google Scholar

[ref97] 97. Amo L, Fargallo JA, Martínez-Padilla J, Millán J, López P, et al. (2005) Prevalence and intensity of blood and intestinal parasites in a field population of a Mediterranean lizard, Lacerta lepida. Parasitol Res 96: 413–417.
View Article
Google Scholar

[282] View Article

[283] Google Scholar

[ref98] 98. Telfer S, Lambin X, Birtles R, Beldomenico P, Burthe S, et al. (2010) Species interactions in a parasite community drive infection risk in a wildlife population. Science 330: 243–246.
View Article
Google Scholar

[285] View Article

[286] Google Scholar

[ref99] 99. Brunham RC, Plummer FA, Stephens RS (1993) Bacterial antigenic variation, host immune response, and pathogen-host coevolution. Infect Immun 61: 2273–2276.
View Article
Google Scholar

[288] View Article

[289] Google Scholar

[ref100] 100. Martínez-de la Puente J, Martínez J, Rivero-de Aguilar J, Herrero J, Merino S (2011) On the specificity of avian blood parasites: revealing specific and generalist relationships between haemosporidians and biting midges. Mol Ecol 20: 3275–3287.
View Article
Google Scholar

[291] View Article

[292] Google Scholar

[ref101] 101. Ishtiaq F, Guillaumot L, Clegg SM, Phillimore AB, Black RA, et al. (2008) Avian haematozoan parasites and their associations with mosquitoes across Southwest Pacific Islands. Mol Ecol 17: 4545–4555.
View Article
Google Scholar

[294] View Article

[295] Google Scholar

[ref102] 102. Hellgren O, Krizanauskiene A, Valkiūnas G, Bensch S (2007) Diversity and phylogeny of mitochondrial cytochrome B lineages from six morphospecies of avian Haemoproteus (Haemosporida: Haemoproteidae). J Parasitol 93: 889–896.
View Article
Google Scholar

[297] View Article

[298] Google Scholar

[ref103] 103. Perkins SL (2001) Phylogeography of Caribbean lizard malaria: tracing the history of vector-borne parasites. J Evol Biol 14: 34–45.
View Article
Google Scholar

[300] View Article

[301] Google Scholar

[ref104] 104. Reardon JT, Norbury G (2004) Ectoparasite and hemoparasite infection in a diverse temperate lizard assemblage at Macraes Flat, South Island, New Zealand. J Parasitol 90: 1274–1278.
View Article
Google Scholar

[303] View Article

[304] Google Scholar

[ref105] 105. Lee KA (2006) Linking immune defenses and life history at the levels of the individual and the species. Integr Comp Biol 46: 1000–1015.
View Article
Google Scholar

[306] View Article

[307] Google Scholar

[ref106] 106. Sacchi R, Scali S, Cavirani V, Pupin F, Pellitteri-Rosa D, et al. (2011) Leukocyte differential counts and morphology from twelve European lizards. Ital J Zool 78: 418–426.
View Article
Google Scholar

[309] View Article

[310] Google Scholar

[ref107] 107. Figuerola J, Munoz E, Gutierrez R, Ferrer D (1999) Blood parasites, leucocytes and plumage brightness in the Cirl Bunting, Emberiza cirlus. Funct Ecol 13: 594–601.
View Article
Google Scholar

[312] View Article

[313] Google Scholar

[ref108] 108. Lindström KM, Foufopoulos J, Pärn H, Wikelski M (2004) Immunological investments reflect parasite abundance in island populations of Darwin's finches. Proc Biol Sci 271: 1513–1519.
View Article
Google Scholar

[315] View Article

[316] Google Scholar

[ref109] 109. Jacquin L, Lenouvel P, Haussy C, Ducatez S, Gasparini J (2011) Melanin-based coloration is related to parasite intensity and cellular immune response in an urban free living bird: the feral pigeon Columba livia. J Avian Biol 42: 11–15.
View Article
Google Scholar

[318] View Article

[319] Google Scholar

[ref110] 110. Westerdahl H, Stjernman M, Råberg L, Lannefors M, Nilsson J-Å (2013) MHC-I affects infection intensity but not infection status with a frequent avian malaria parasite in blue tits. PLoS One 8: e72647.
View Article
Google Scholar

[321] View Article

[322] Google Scholar

[ref111] 111. Ujvari B, Madsen T (2005) Age, parasites, and condition affect humoral immune response in tropical pythons. Behav Ecol 17: 20–24.
View Article
Google Scholar

[324] View Article

[325] Google Scholar

[ref112] 112. Salkeld DJ, Schwarzkopf L (2005) Epizootiology of blood parasites in an Australian lizard: a mark-recapture study of a natural population. Int J Parasitol 35: 11–18.
View Article
Google Scholar

[327] View Article

[328] Google Scholar

[ref113] 113. Salvador A, Veiga JP, Martin J, Lopez P, Abelenda M, et al. (1996) The cost of producing a sexual signal: testosterone increases the susceptibility of male lizards to ectoparasitic infestation. Behav Ecol 7: 145–150.
View Article
Google Scholar

[330] View Article

[331] Google Scholar

[ref114] 114. Restif O, Amos W (2010) The evolution of sex-specific immune defences. Proc Biol Sci 277: 2247–2255.
View Article
Google Scholar

[333] View Article

[334] Google Scholar

[ref115] 115. Lachish S, Knowles SCL, Alves R, Sepil I, Davies A, et al. (2013) Spatial determinants of infection risk in a multi-species avian malaria system. Ecography 36: 587–598.
View Article
Google Scholar

[336] View Article

[337] Google Scholar

[ref116] 116. Møller AP, Merino S, Soler JJ, Antonov A, Badás EP, et al. (2013) Assessing the effects of climate on host-parasite interactions: a comparative study of European birds and their parasites. PLoS One 8: e82886.
View Article
Google Scholar

[339] View Article

[340] Google Scholar

[ref117] 117. Ferraguti M, Martínez-de la Puente J, Muñoz J, Roiz D, Ruiz S, et al. (2013) Avian Plasmodium in Culex and Ochlerotatus Mosquitoes from Southern Spain: Effects of Season and Host-Feeding Source on Parasite Dynamics. PLoS One 8: e66237.
View Article
Google Scholar

[342] View Article

[343] Google Scholar

[ref118] 118. Altizer S, Dobson A, Hosseini P, Hudson P, Pascual M, et al. (2006) Seasonality and the dynamics of infectious diseases. Ecol Lett 9: 467–484.
View Article
Google Scholar

[345] View Article

[346] Google Scholar

[ref119] 119. Uchii K, Telschow A, Minamoto T, Yamanaka H, Honjo MN, et al. (2011) Transmission dynamics of an emerging infectious disease in wildlife through host reproductive cycles. ISME J 5: 244–251.
View Article
Google Scholar

[348] View Article

[349] Google Scholar

[ref120] 120. Huyghe K, Van Oystaeyen A, Pasmans F, Tadić Z, Vanhooydonck B, et al. (2010) Seasonal changes in parasite load and a cellular immune response in a colour polymorphic lizard. Oecologia 163: 867–874.
View Article
Google Scholar

[351] View Article

[352] Google Scholar

[ref121] 121. Møller AP, Erritzøe J, Saino N (2003) Seasonal changes in immune response and parasite impact on hosts. Am Nat 161: 657–671.
View Article
Google Scholar

[354] View Article

[355] Google Scholar

[ref122] 122. Maia JPMC, Harris DJ, Perera A (2011) Molecular survey of Hepatozoon species in lizards from North Africa. J Parasitol 97: 513–517.
View Article
Google Scholar

[357] View Article

[358] Google Scholar

Figures

Abstract

Introduction

Materials and Methods

Study species and study site

Microscopic examination

DNA extraction and sample preparation

Conventional PCR, sequencing and phylogenetic analysis

qPCR design and protocol

Statistical analyses

Between methods' comparisons.

Between hosts' comparisons.

Results

qPCR assay validation

Parasite diversity and identification

Methodological comparison

Between-host differences in infection patterns

Discussion

Methodological recommendations

Between-host differences in infection patterns

Conclusion

Supporting Information

Figure S1.

Figure S2.

Table S1.

Acknowledgments

Author Contributions

References