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BRIEF RESEARCH REPORT article

Front. Vet. Sci., 14 October 2020
Sec. Parasitology
This article is part of the Research Topic Neglected and Under-Researched Parasitic Diseases of Veterinary and Zoonotic Interest View all 18 articles

Diversity of Eimeria Species in Wild Chamois Rupicapra spp.: A Statistical Approach in Morphological Taxonomy

\nFederica Berrilli
Federica Berrilli1*Margherita Montalbano Di Filippo&#x;Margherita Montalbano Di Filippo1Claudio De LiberatoClaudio De Liberato2Ilaria Marani&#x;Ilaria Marani1Paolo LanfranchiPaolo Lanfranchi3Nicola FerrariNicola Ferrari3Tiziana TroguTiziana Trogu4Nicoletta FormentiNicoletta Formenti4Francesco FerrettiFrancesco Ferretti5Luca RossiLuca Rossi6Stefano D&#x;AmelioStefano D'Amelio7Annunziata GiangasperoAnnunziata Giangaspero8
  • 1Department of Clinical Sciences and Translational Medicine, Tor Vergata University, Rome, Italy
  • 2Istituto Zooprofilattico Sperimentale del Lazio e della Toscana “M. Aleandri”, Rome, Italy
  • 3Department of Veterinary Medicine, Università degli Studi di Milano, Milan, Italy
  • 4Istituto Zooprofilattico Sperimentale della Lombardia e dell'Emilia Romagna “Bruno Ubertini”, Brescia, Italy
  • 5Department of Life Sciences, University of Siena, Siena, Italy
  • 6Department of Veterinary Sciences, University of Turin, Grugliasco, Italy
  • 7Department of Public Health and Infectious Diseases, Sapienza University of Rome, Rome, Italy
  • 8Department of Science of Agriculture, Food and Environment, University of Foggia, Foggia, Italy

Wildlife is frequently infected by intestinal protozoa, which may threaten their fitness and health. A diverse community of Eimeria species is known to occur in the digestive tract of mountain-dwelling ungulates, including chamois (genus Rupicapra). However, available data on Eimeria diversity in these taxa is at times inconsistent and mostly dated. In the present study, we aimed to revisit the occurrence of Eimeria spp. in the Alpine subspecies of the Northern chamois (Rupicapra rupicapra rupicapra) and the Apennine subspecies of the Southern chamois (Rupicapra pyrenaica ornata) in Italy, using an integrated approach based on a hierarchical cluster analysis (HCPC) applied to oocyst morphology and morphometry. A total of 352 fecal samples were collected from R. r. rupicapra (n = 262) and R. p. ornata (n = 90). Overall, 85.3% (300/352) of the animals tested microscopically positive to Eimeria spp. Based on morphological analysis, we identified all the eimerian species described in chamois. Through the HCPC method, five clusters were generated, corresponding to E. suppereri, E. yakimoffmatschoulskyi, E. riedmuelleri (two different clusters), and E. rupicaprae morphotypes. The well-defined clusters within E. riedmuelleri support the existence of two distinct morphological groups, possibly referable to different taxonomic units. This study suggests that combining a morphometrical approach with a powerful statistical method may be helpful to disentangle uncertainties in the morphology of Eimeria oocysts and to address taxonomic studies of eimeriid protozoa at a specific host taxon level.

Introduction

Exploring the parasite communities in wild animals represents a main challenge for wildlife management, as several parasites may have an impact on their fitness and health, even more so in the frequent event of co-infections (1). Moreover, wildlife can play an important role as reservoirs of pathogens of medical and/or veterinary importance (2).

Wild caprines (Bovidae, Caprinae) are reportedly known to harbor rich parasite communities including representatives of the genus Eimeria Schneider, 1875 (Coccidia, Apicomplexa) (3). In particular, five Eimeria species have been described to infect the iconic members of the genus Rupicapra: Eimeria alpina Supperer and Kutzer, 1961; Eimeria riedmuelleri Yakimoff and Matschoulsky, 1940; Eimeria rupicaprae Galli-Valerio, 1924; Eimeria suppereri Kutzer, 1964 and Eimeria yakimoffmatschoulskyi Supperer and Kutzer, 1961 (4). These species have never been reported in other ruminants, thus advocating for their strict host specificity.

Traditionally, Eimeria species identification is obtained using a set of biological traits and morphological features such as the identity of the host species as well as oocyst size, shape and structure (curvature, presence/absence of oocyst residuum, conspicuous/inconspicuous micropyle), shape and structure of the sporocysts (5, 6). However, morphological methods are often challenging and several other Eimeria species from Rupicapra spp. have been inadequately or erroneously described. As stated in Levine and Ivens (4), the name Eimeria longispora Rudovsky 1922, identified in chamois from Austria, should be considered as nomen nudum, due to its incomplete description; moreover, the report of Eimeria arloingi, Eimeria crandallis, Eimeria ninakohlyakimovae, and Eimeria parva in R. rupicapra in the present-day Slovakia and of E. arloingi and E. ninakohlyakimovae in the present-day Slovenia (7, 8) should be considered uncertain; finally the occurrence of Eimeria faurei in hosts other than Ovis and Capra is doubtful.

In Italy, two taxa of chamois are present (9): the Alpine subspecies of the Northern chamois (Rupicapra rupicapra rupicapra), widely spread along the Alps, and the Apennine subspecies of the Southern chamois (Rupicapra pyrenaica ornata), which occurs in five protected areas of central Apennines. Due to its limited and fragmented distribution range as well as the small population size, R. p. ornata is currently included in the International Union for Conservation of Nature (IUCN) red list in the category of “vulnerable” taxa (VU D1+2) (www.iucn.it). Despite the relevance of R. r. rupicapra and R. p. ornata, which cover a large geographical area, data on Eimeria spp. in wild chamois from Italy are not only limited but also still leave open questions on their identity and prevalence. Indeed, in the Alpine chamois R. r. rupicapra, E. rupicaprae identification dates back to 1950's through a parasitological survey on the fauna of the Gran Paradiso National Park (Western Alps) (10) and about 20 years later, E. rupicaprae, E. riedmuelleri, and E. yakimoffmatschoulskyi were described in Eastern Alps (11). More recently, Stancampiano et al. (12) confirmed the presence of E. riedmuelleri and E. yakimoffmatschoulskyi in R. r. rupicapra, and recorded E. suppereri for the first time in Italy; more intriguingly, a coccidian species resembling E. faurei, a species related to domestic sheep was also described (12). As regards the Apennine chamois R. p. ornata, only one survey has been carried out in Italy, reporting E. rupicaprae and E. riedmuelleri (13). Furthermore, E. alpina and E. yakimoffmatschoulskyi have been recorded by Rossi et al. (14).

Despite the recent advances in morphological, morphometrical, statistical, and molecular biology-based approaches, which may be utilized to investigate the identity of coccidian oocysts, the use of a single methodology is unable to fully characterize these structures and different tools should be applied for taxonomic purposes (6). Therefore, in order to overcome the issues related to the traditional approach to taxonomy of Eimeria, the aim of this work was to combine morphological characterization of the oocysts with a statistical method to refine knowledge of Eimeria species in Alpine and Apennine chamois.

Materials and Methods

From September 2013 to November 2015, fecal samples (n = 262) were collected from R. r. rupicapra in Italian Central Alps. The chamois originated from (i) a hunting territory in Lombardy region, with an area of 253 km2 (45°59'N, 9°32'E) (A); (ii) two contiguous areas in northern Piedmont (46°07'N, 8°17'E) with different population management: a hunting district (B), which extends over 727 km2 and a protected area (C) of 85, 39 km2 where hunting is banned (Figure 1), and fresh stool samples were collected from the ground soon after defecation. In the same period, fresh fecal samples of R. p. ornata (n = 90) were collected after observing defecation, from individuals grazing on upper grasslands, in three subareas of the Abruzzo, Lazio and Molise National Park (D to F, Figure 1). All samples were stored in 2.5% potassium dichromate in a 50-ml tight screw cap plastic tube under constant aeration for sporulation for a minimum of two weeks at room temperature until microscopical analysis.

FIGURE 1
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Figure 1. Schematic map of Italy showing the geographical location of sampling sites (A–F) and animal hosts analyzed in the present study.

Eimeria oocysts were recovered by flotation in saline solution (density 1,200), while quantitative analysis was performed using a McMaster technique, with a lower detection limit of 50 oocysts per gram of feces (o.p.g.) (15). Morphometrical and morphological features of oocysts and of sporocysts were used for species identification based on the description in Levine and Ivens (4). In particular, their shape, width and length, the oocyst color, rough or smooth wall, the presence/absence of the oocyst micropyle and/or cap, were carefully scrutinized and photographed using a Leica DMD108 microscope, equipped with an integrated camera and image analysis system, by 60 X objective lenses. All measurements are in micrometers (μm).

A statistical analysis with R software v 1.1.463 (FactoMine and factoextra packages) was performed to obtained data, using the Hierarchical Clustering on Principal Components (HCPC) approach on a dataset of 292 sporulated oocysts. The parameters used were length, width and the length/width ratio (Shape index, L × W) for both oocysts and sporocysts. We decided to employ the HCPC approach as it makes possible to combine the three standard methods used in multivariate data analyses (16): (i) principal component methods (PCA, CA, MCA, FAMD, MFA), (ii) hierarchical clustering, and (iii) partitioning clustering, particularly the k-means method. Furthermore, the HCPC analysis allows the characterization of clusters of specimens based on all characters and on subsets of characters, weighting all characters equally.

Results

Overall, 85.3% (300/352) (95%, C.I. = 81.5–89.1) of samples were microscopically positive to Eimeria spp., with a mean intensity of up to 776 o.p.g. Prevalence in R. r. rupicapra was 81.2% (213/262) (95%, C.I. = 77.1–86.8), with a mean intensity of 380 o.p.g.; in R. p. ornata the prevalence was 94.4% (85/90) (95%, C.I. = 89.7–99.2), with a mean intensity of 1,093 o.p.g.

Based on morphological analysis of oocysts, three morphotypes attributable to E. rupicaprae, E. riedmuelleri, and E. yakimoffmatschoulskyi were detected in both chamois species. In addition, E. suppereri was recognized in R. r. rupicapra from Area B and, noteworthy, two small oocysts recovered from one chamois originated from Area A and consistent with the descriptions of E. alpina were identified. Due to the absence of sporulated forms, these two oocysts were excluded from the statistical analysis.

Through the HCPC analysis, five well-defined clusters (k = 5) grouping oocysts from both hosts were generated (see Table 1 and Figure 2). In summary, clustering was as follows:

TABLE 1
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Table 1. Morphological data of Eimeria oocysts and sporocysts isolated from Italian chamois (Rupicapra spp.).

FIGURE 2
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Figure 2. Circular dendrogram issued from the HCPC analysis (output of k = 5) based on length, width and shape index for both Eimeria spp. oocysts and sporocysts.

Cluster 1 (red cluster) gathers the biggest oocysts (n = 4) of our dataset, measuring on average 47.54 by 35.38 μm; the mean measures of the sporocysts were 19.48 by 10.88 μm. These isolates were assigned to E. suppereri. Cluster 2 (light blue cluster) grouped 37 oocysts measuring on average 29.71 by 21.3 μm. The sporocysts measured 13.74 by 6.92 μm. We attributed these isolates to E. yakimoffmatschoulskyi. Cluster 3 (dark blu cluster) includes 75 oocysts measuring 27.02 by 22.33 μm. The sporocysts were 11.75 by 7.71 μm. We assigned these isolates to E. rupicaprae. Cluster 4 (light green cluster) consists of 82 spherical oocysts with a mean size of 18.28 by 16 μm. The sporocysts were 7.57 by 5.99 μm. We assigned these isolates to the spherical form of E. riedmuelleri. Finally, Cluster 5 (dark green cluster) pools 96 oocysts measuring on average 20.21 by 17.4 μm. The sporocysts were 8.14 by 6.24 μm. These isolates were assigned to the ovoid/ellipsoidal E. riedmuelleri form.

A detailed description of morphometrical data is given in Table 1.

Discussion

Eimeriid protozoans are common parasites in ruminants worldwide, often associated with enteritis, weight loss and mortality in young animals (17). High prevalence and intensity of infection have been also documented in wild ungulates, where asymptomatic infection largely prevail (18). The high prevalence and intensity of oocysts emission recorded in this study shows that infection by eimeriid protozoa is also widespread amongst members of the Rupicapra genus in Italy, confirming previous findings (12, 19). The normal fecal consistency of analyzed samples suggests that infection by Eimeria spp. is substantially sub-clinical in both hosts.

To overcome the considerable amount of intraspecific and interspecific variation exhibited in the key morphological features of oocysts, and the drawbacks linked to the presence of multiple infections, as usually occurs in wildlife, in the present study a statistical method was performed for the identification of Eimeria spp. The hierarchical cluster analysis adopted here was able not only to verify the robustness of original taxonomic description of the Eimeria species known to parasitize the members of the genus Rupicapra, but, noteworthy, to provide a statistical significance to their morphological variability. Cluster analysis (see Figure 2) highlights that distinct forms can be separated based upon their morphology. As reported in Levine and Ivens (4), the measurements obtained from the oocysts grouped in Cluster 1 and 2 overlap unequivocally with the values describing E. suppereri and E. yakimoffmatschoulskyi according to Restani (11), respectively; Cluster 3, grouping oocysts of E. rupicaprae corresponds more strictly to Restani (11) measurements than to those by Galli-Valerio (20, 21) and Yakimoff and Matschoulsky (22). Surprisingly, within the species E. riedmuelleri, the splitting of the two well-defined Clusters 4 and 5 was in line with the two morphotypes (the spherical and the ovoid or ellipsoidal oocysts) described by Yakimoff and Matschoulsky (22) and Levine and Ivens (4). Hence, our results based on statistical method strongly support the existence of these distinct morphological groups, possibly referable to two different taxonomic entities infecting chamois, whose identity requires further in-depth investigations.

Remarkably, the Northern and Southern chamois shared most of the Eimeria species identified, suggesting that wild Caprines may be a suitable model to explore in depth the amplitude of the host specificity characterizing eimeriid protozoa (23, 24).

The absence of the large-sized, hence easy detectable, E. suppereri in the Southern chamois might reflect a possible effect of the life history of the Apennine subspecies of R. pyrenaica ornata, characterized by prolonged population bottlenecks (9, 25).

In conclusion, this study provides a deepening into the diversity of Eimeria species and highlights the not negligible prevalence of these coccidian protozoan infecting chamois in Italy. The presence of E. rupicaprae, E. yakimoffmatschoulskyi, E. suppereri and of E. riedmuelleri in R. r. rupicapra and of E. riedmuelleri, E. rupicaprae in R. p. ornata is confirmed. Moreover, E. alpina and E. yakimoffmatschoulskyi are additional species of the eimerian fauna of the Northern and Southern chamois. The combination of morphological data with a robust statistical method, as here proposed, represents a useful approach to infer the taxonomy and, consequently, to investigate the epidemiology of these protozoans with the due accuracy.

Data Availability Statement

The raw data supporting the conclusions of this article will be made available by the authors, without undue reservation.

Ethics Statement

Ethical review and approval was not required for the animal study because this research did not involve purposeful killing of animals. Fecal samples in hunting districts were gathered from chamois legally shot by hunters in accordance with the Italian Law (157 of 11/02/1992) which implies that hunters have to carry culled wild ungulates to the control centers where, for each subject, age, sex, the shooting area, and morpho-biometric measures are registered. Thus, no animals were killed specifically for this study.

Author Contributions

FB, PL, LR, MMDF, SD'A, and AG participated in study activities and in drafting and revising the manuscript. CDL, IM, NF, TT, NF, and FF participated in the field and laboratory work. MMDF performed the statistical analysis. All Authors have participated in critically revising the manuscript.

Funding

This study was funded by MIUR-Relevant Italian Project (PRIN) grant number: 2010P7LFW4 (2013–2016) - Genomics and host–pathogen interactions: a model study in the One-Health perspective.

Conflict of Interest

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

The handling Editor declared a past co-authorship with the authors SD'A.

Acknowledgments

The Authors are grateful to the Members and Management Committee of the Alpine hunting districts (Alpi Lecchesi, Prealpi Lecchesi and VCO2-Ossola Nord), of the Alpe Veglia-Alpe Devero Natural Park) and to the Abruzzo, Lazio and Molise National Park Agency for their logistic support; Davide Scornavacca and the students for their help in field activities; Prof. Sandro Lovari for his support throughout the study.

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Keywords: Eimeria spp., Rupicapra spp., morphology, hierarchical clustering, Italy

Citation: Berrilli F, Montalbano Di Filippo M, De Liberato C, Marani I, Lanfranchi P, Ferrari N, Trogu T, Formenti N, Ferretti F, Rossi L, D'Amelio S and Giangaspero A (2020) Diversity of Eimeria Species in Wild Chamois Rupicapra spp.: A Statistical Approach in Morphological Taxonomy. Front. Vet. Sci. 7:577196. doi: 10.3389/fvets.2020.577196

Received: 28 June 2020; Accepted: 04 September 2020;
Published: 14 October 2020.

Edited by:

David Modrý, University of Veterinary and Pharmaceutical Sciences Brno, Czechia

Reviewed by:

Jana Kvicerova, University of South Bohemia, Czechia
Alessio Giannelli, Poulpharm BVBA, Belgium

Copyright © 2020 Berrilli, Montalbano Di Filippo, De Liberato, Marani, Lanfranchi, Ferrari, Trogu, Formenti, Ferretti, Rossi, D'Amelio and Giangaspero. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

*Correspondence: Federica Berrilli, YmVycmlsbGkmI3gwMDA0MDt1bmlyb21hMi5pdA==

Present address: Margherita Montalbano Di Filippo, Istituto Superiore di Sanità - Dipartimento di Sicurezza Alimentare, Nutrizione e Sanità Pubblica Veterinaria, Rome, Italy
Ilaria Marani, Istituto Zooprofilattico Sperimentale del Lazio e della Toscana “M. Aleandri”, Rome, Italy

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