Abstract
Calodium hepaticum (Nematoda; Capillariidae) is a parasitic nematode of mammals with a cosmopolitan distribution. Adults of this nematode can infect the liver of many mammalian species, including humans, but the main hosts are members of the superfamily Muroidea. Among these, Rattus spp. have the highest apparent prevalences reported worldwide. There are only two reports of C. hepaticum infecting Sigmodontinae species (Muroidea: Cricetidae). In this survey, we examined the occurrence of C. hepaticum in two assemblages of Sigmodontinae rodents from Argentina (Santa Fe and Entre Ríos provinces). The diagnosis was made by morphological features, histopathological exam, and molecular characterization of 18S ribosomal RNA gene region. Here, we show that C. hepaticum is a common parasite of Sigmodontinae. We report the infection in six species (all new hosts): Akodon azarae, Calomys callidus, Calomys venustus, Oligoryzomys flavescens, Oligoryzomys nigripes, and Oxymycterus rufus. This is the first report of C. hepaticum in Sigmodontinae rodents from Argentina and the second record in this subfamily for South America. It is also the first confirmation of C. hepaticum infection in Sigmodontinae by molecular diagnosis. The genetic findings and the prevalences observed, together with the existing information on C. hepaticum, lead us to propose that Rattus spp. brought C. hepaticum to the New World exposing Sigmodontinae rodents, which are frequently infected by this parasite. The high prevalence of infection in A. azarae (41.2%) suggests that this host may be playing an important role in C. hepaticum dynamics in the New World.
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Introduction
Calodium hepaticum Moravec, 1982 (Nematoda, Capillariidae) is a cosmopolitan parasite of mammals, including humans (Ferreira and Andrade 1993; Duque et al. 2012; Fuehrer et al. 2011; Fuehrer 2014a, b). The main hosts of this parasite are rodents of the superfamily Muroidea (Fuehrer 2014a). Adults of C. hepaticum are found in the liver. Hepatic infections occur following ingestion of embryonated eggs by a mammal. After hatching, the larvae penetrate through the intestinal wall, migrate into the hepatic portal system, and develop as adults in the hepatic parenchyma (Spratt and Singleton 2001). Gravid females lay immature eggs there, and they are exposed to the next host after the death and decomposition of the infected host or when it becomes prey (Spratt and Singleton 2001; Camargo et al. 2010). Rothenburger et al. (2014) suggested that cannibalism may be important in transmission among rats.
Among the Muroidea rodents, C. hepaticum has been reported in over 90 host species of at least 44 genera of the families Muridae (Murinae, Deomyinae) and Cricetidae (Arvicolinae, Neotominae, Cricetinae, Sigmodontinae, Gerbilinae, and Cricetomyinae) (Fuehrer 2014a). However, this parasite is found frequently and at high prevalences (> 50%) in rats (Rattus spp.), for which rats are considered the main hosts of C. hepaticum (Ceruti et al. 2001; Spratt and Singleton 2001; Duque et al. 2012; Moreira et al. 2013; Fuehrer 2014a; Simões et al. 2014). In the New World, the predominant Muroidea rodents are the Sigmodontinae, which comprise 381 species (D’Elia and Pardiñas 2015). Many of them live in sympathry with the introduced Murinae Rattus norvegicus Berkenhout, 1769 and Rattus rattus Linnaeus, 1758. Despite the large diversity of Sigmodontinae present across the Americas, C. hepaticum has only been recorded in Akodon venezuelensis Allen, 1899 and Sigmodon hispidus Say & Ord, 1825, both diagnosed through morphological exam (Vogelsang and Espin 1949; Kinsella 1974). Diagnosis of C. hepaticum infection by molecular techniques has not been reported in Sigmodontinae. Recently, there has been an increase in the molecular analyses of Trichinelloidea nematodes (including works on Trichuridae and Capillaridae) from rodents (e.g., Robles et al. 2014, 2018; Callejón et al. 2016). Particularly, a study had clarified the phylogenetic position of C. hepaticum among the capillarids and the relationships between some species of two families, Capillariidae and Trichuridae (Guardone et al. 2013).
In this context, the aim of this paper was to document the occurrence of C. hepaticum in two rodent assemblages of central Argentina, basing the diagnosis on morphological characteristics, histopathological exam, and 18S ribosomal RNA sequences. Also, we provide a comprehensive summary of existing records from rodents in South America and compare our molecular findings with previous genetic studies.
Materials and methods
Data collection
A total of 409 Sigmodontinae rodents were trapped in Esperanza (ES), Santa Fe Province (31° 24′ 20″ S–60° 58′ 16″ W) and La Picada (LP), Entre Ríos Province (31° 44′ 06″ S–60° 21′ 53″ W), Argentina, during several field trapping sessions carried out between June 2014 and September 2016. Rodents captured were identified to the species level by assessing cranium morphology (Massoia and Fornes 1965; Massoia 1973; Goncalvez and De Oliveira 2004). The Sigmodontinae species captured and total count were as follows: Akodon azarae Fischer, 1829 (n = 119 ES and 26 LP), Calomys callidus Thomas, 1916 (n = 29 LP), Calomys venustus Thomas, 1894 (n = 101 ES), Holochilus chacarius Thomas, 1906 (n = 14 ES and 2 LP), Necromys lasiurus Lund, 1840 (n = 5 ES), Oligoryzomys flavescens Waterhouse, 1837 (n = 42 ES and 9 LP), Oligoryzomys nigripes Olfers, 1818 (n = 15 ES), and Oxymycterus rufus Fischer, 1814 (n = 47 LP).
All captured specimens were necropsied, and livers were dissected and stored in plastic bags with ethanol (70%). At the laboratory, they were examined under a stereoscopic microscope in order to observe lesions consistent with C. hepaticum infection. The worm parts that could be recovered from the lesions were cleared in lactophenol, studied under light microscope, and then identified following Wright (1961). In a subset of samples, diagnosis was complemented by histopathology (following routine procedures) and by molecular determination.
The prevalence (P) of C. hepaticum in each host population was estimated by macroscopic and microscopic exams of the lesions and helminths (as only part of the sample was processed by histopathology or molecular techniques) and was calculated following Bush et al. (1997).
Molecular determination
Three specimens morphologically identified as C. hepaticum (two from A. azarae and one from C. callidus) were washed extensively in 0.9% saline solution and stored in 70% ethanol until used for PCR and sequencing. Genomic DNA from individual worms was extracted using the AccuPrep® Genomic DNA Extraction Kit (Bioneer) according to the manufacturer’s protocol. Genomic DNA concentration and purity were assessed using the SPECTROstar Nano and the MARS Data Analysis Software (BMG Labtech, Germany). 18S rRNA partial gene was amplified by the polymerase chain reaction (PCR), using primers 18S 965 and 18S 1573R (Powers et al. 2009). The PCR was performed in an Ivema T-18 thermocycler (Ivema Desarrollos, Argentina) using 5 μl of 5× Phire® reaction buffer, 200 μM dNTP, 0.4 pM of each primer, 100 ng of genomic DNA, and 0.5 μl of Phire® Hot Start II DNA polymerase (Finnzymes, Finland) and completed to 25 μl with molecular grade water. PCR conditions were as follows: 1 cycle at 98 °C for 3 min, followed by 35 cycles at 98 °C for 10 s, 57 °C for 20 s, 72 °C for 35 s; and 1 final cycle at 72 °C for 5 min. A negative control was included in each amplification run.
A phylogenetic analysis using the 18S rRNA sequences obtained in this study and others from closely related species previously published in the GenBank was performed with the maximum likelihood (ML) method by using the program MEGA 5.0 (Tamura et al. 2011). Best fitting substitution models were determined with the Akaike information criterion using the ML model test implemented in MEGA 5.0. Support for the topologies was tested by bootstrapping over 1000 replications.
Results
In the present survey, we found liver lesions consistent with C. hepaticum infection in 64 of 409 rodents (15.6%), recovering in all cases female nematodes and eggs. Table 1 shows details of the findings by site and host species. The most frequently parasitized species was A. azarae.
Male specimens were not found. The morphological characters observed in female specimens agree with the description given by Wright (1961).
A fragment of the 18S rRNA gene was amplified from three adult female worms. These worms were obtained from heavily parasitized hosts (two A. azarae and one C. callidus) and were selected because they could be dissected completely, being free from host liver tissue. The resulting sequences (excluding primers) were 100% identical (600/600) to the corresponding 18S rRNA sequence of C. hepaticum (KT875351) obtained from R. norvegicus in Argentina. Complete identity was also observed with smaller overlapping segments of 18S rRNA of C. hepaticum from other hosts in the Old World (JX456635, Switzerland, Arvicola terrestris Linnaeus, 1758) (Guardone et al. 2013). The phylogenetic tree (Fig. 1) inferred from maximum likelihood analysis of the 18S rRNA sequences from C. hepaticum and other species of Trichinelloidea showed that C. hepaticum from Argentina nested in a clade together with C. hepaticum from Italy, Switzerland, Poland, and Turkey. Consensus sequence from C. hepaticum 18S rRNA gene from this study was deposited in GenBank (accession number MG686613).
Histopathology of 40 subsamples identified lesions consistent with C. hepaticum infection.
Discussion
In this study, we report C. hepaticum infection in six Sigmodontinae species, all new hosts for this parasite. This is the first report of C. hepaticum in Sigmodontinae rodents from Argentina and the second record in this subfamily for South America. In addition, this is the first report of C. hepaticum in Sigmodontinae rodents confirmed by molecular analysis. In Table 2, we offer a summary of the existing reports C. hepaticum in Muroidea rodents from South America, including the results of this survey.
Spratt and Singleton (2001) described that C. hepaticum females move through host hepatic parenchyma, destroying hepatocytes. Subsequent encapsulation is by fibrous connective tissue of the host (Rothenburger et al. 2014). Interestingly, there are no studies describing the sex of adult C. hepaticum recovered from the liver. The absence of males in the liver parenchyma is surprising and suggests that new studies should establish whether they are naturally scarce or if they are present in other organs.
The dendrogram based on partial 18S rRNA gene sequences (Fig. 1) shows a remarkable separation of Capillariidae nematodes, where one clade groups respiratory parasites (Eucoleus aerophilus, Eucoleus boehmi, and Eucoleus dispar) and another capillarids colonizing abdominal organs of mammals (Calodium splenaecum, Aonchotheca putorii, Pearsonema plica, and C. hepaticum), as previously shown by Guardone et al. (2013). No difference was observed between the 18S rRNA sequences obtained from C. hepaticum hosted in Sigmodontinae in the present study and those reported from C. hepaticum hosted in Rattus spp. from different geographical origins (Argentina, KT875351, and Poland, KY488184) and in Arvicola terrestris Linnaeus, 1758 (Switzerland, JX456635-JX456636). Moreover, a minimal difference was observed (599/600 bp) when compared to the 18S rRNA sequence of C. hepaticum infesting Cricetulus migratorius Pallas, 1773 (Turkey, MF287972) and Vulpes vulpes Linnaeus, 1758 (Italy, JX456631-JX456634). Previous studies demonstrated that dissemination of invasive species, as Rattus spp., played a key role in the introduction of parasites in new geographical areas (Hayman et al. 2013; Kosoy et al. 2015; Puckett et al. 2016), which in turn may lead to altered parasite community dynamics (Telfer et al. 2010). In this regard, our results suggest that C. hepaticum originally circulating in Europe and Asia might have been introduced into the New World by rats, which transmitted the parasite to sigmodontine rodents. So far, paleoparasitological studies found no evidence of the presence of this parasite prior to rat introductions in the New World. However, further research on the phylogeography of C. hepaticum is necessary to test this hypothesis. Like in other parts of the world, in South America, Rattus spp. have high prevalence of C. hepaticum, ranging from 2 to 83% (see Table 2). In Argentina, C. hepaticum was only reported in R. norvegicus with a prevalence above 30% in Buenos Aires Province (Hancke et al. 2011). The only previous reports of C. hepaticum in Sigmodontinae rodents are Akodon venezuelensis from Venezuela (Vogelsang and Espin 1949) and S. hispidus from Florida, USA (Kinsella 1974); however, these diagnoses were attained only by assessment of the presence/absence of gross lesions. The prevalences reported here in Sigmodontinae rodents were lower than those found in rats, except for A. azarae from Santa Fe, where the prevalence was 41.2%.
In summary, an analysis of the genetic findings and the prevalences observed here, together with the existing information on C. hepaticum, leads us to propose that Rattus spp. brought C. hepaticum to the New World exposing Sigmodontinae rodents, which are frequently infected by this parasite. The prevalence levels observed in A. azarae suggest that this host may be playing an important role in C. hepaticum dynamics in the New World.
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Acknowledgements
Special thanks are given to Pablo Teta and Ulyses Pardiñas for the identification of the hosts; Pablo Cuervo for the help in the assembly of the figures; Alfredo Berduc, María Lucía Reynoso, Camilo Andrés Fernandez, Agustín Fasano, Ivana Monsalvo, Natalia Mordini, Tamara Ricardo, Pablo Hernán Capovilla, and Cintia Palavecino for their collaboration during fieldwork.
Funding
María C. Fantozzi is a fellow of the Consejo Nacional de Investigaciones Científicas y Técnicas (CONICET, Argentina). This study was supported by grants from CONICET and Agencia Nacional de Promoción Científica y Tecnológica (ANPCyT), project number: PICT 2012-1552.
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Sample collection was carried out during fieldwork under official permits granted by the Dirección General de Recursos Naturales, Gobierno de Entre Ríos (autorización no. 002/14 and 001/16, Expediente 1.657.179) and Ministerio de Aguas, Servicios Públicos y Medio Ambiente, Gobierno de Santa Fe (authorization number 193, file 02101-0014145-3). This study was carried out in accordance with protocol no. 135/12 approved by the bioethics committee of Facultad de Ciencias Veterinarias, Universidad Nacional del Litoral. Specimens collected in live traps were humanely sacrificed (euthanized by cervical dislocation while being deeply anesthetized with isoflurane), following the recommendations of the Ethics Committee for Research on Laboratory Animals, Farm and Obtained from Nature of the National Council of Scientific and Technical Research (CONICET), and subsequently by ANPCCyT. No endangered species were involved in this study.
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Fantozzi, M.C., Robles, M.d., Peña, F.E. et al. Calodium hepaticum (Nematoda: Capillariidae) in wild rodent populations from Argentina. Parasitol Res 117, 2921–2926 (2018). https://doi.org/10.1007/s00436-018-5983-7
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DOI: https://doi.org/10.1007/s00436-018-5983-7