First Record in Brazil of Epistylis sp. (Ciliophora) Adhered to Argulus sp. (Argulidae), a Parasite of Hoplias aimara (Eritrhinidae)


This paper records the first occurrence of Epistylis sp. on the body surface of Argulus sp. parasitizing Hoplias aimara from the upper Araguari River, in the eastern Amazon region, in the north of Brazil. Of the 16 specimens of H. aimara examined, 93.7% had their pelvic, caudal and pectoral fins and tegument infested by Argulus sp. (n = 73), which in turn were infested by Epistylis sp. The specimens of Epistylis sp. from the body surface of Argulus sp. were analyzed using Scanning Electron Microscopy (SEM). The present study also identified a widening of the geographic distribution of these two species of ectoparasites to the eastern Amazon region of Brazil.

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Corrêa, L. , Oliveira, M. , Prestes, L. and Tavares-Dias, M. (2016) First Record in Brazil of Epistylis sp. (Ciliophora) Adhered to Argulus sp. (Argulidae), a Parasite of Hoplias aimara (Eritrhinidae). Natural Resources, 7, 331-336. doi: 10.4236/nr.2016.76029.

Received 25 April 2016; accepted 10 June 2016; published 13 June 2016

1. Introduction

Hoplias aimara Valenciennes, 1847 is a Characiforme from the Erythrinidae family which is distributed from Central America to Argentina, and is popularly known as giant lungfish, lungfish or Aymara. In Brazil, this species is distributed in the Trombeta, Xingu, Tapajós, Jari, Tocantins and Araguari Rivers, as well as the coastal rivers of Surinam and French Guyana [1] [2] . This fish lives in a variety of habitats, from lotic environments such as large rivers and waterfalls to lentic environments such as lakes and reservoirs [3] . However, little is known about the parasites that the fish hosts.

Among Branchiura Thorell, 1818 crustaceans, species of the genus Argulus Müller, 1785 are highly adapted to ectoparasitism in different fish species [4] - [6] . Some Argulus spp. are endemically distributed in the region of the Brazilian Amazon [6] . These ectoparasite crustaceans can reduce the weight, growth rates, breathing capacity, and muscle and fat percentage of fish, and lead to tissue traumatization. The severity of parasitic infection mainly depends on the infestation intensity. When it is high, there may be fish mortality, causing damage to fishing and fish farming [4] [7] - [9] .

Species of Epistylis Ehrenberg, 1830 are colony forming ciliates of whom several species are free-living (freshwater and marine) or live in epibiosis, colonizing the body surface of insects and aquatic plants, mollusks, amphibians, reptiles, rotifers and fish. In fish, the main organ colonized is the gills and in Brazil, Epistylis sp. is an emerging parasite [10] [11] . The death of thousands of Centrarchidae in the USA has been attributed to heavy infestation by Epistylis sp., which coincide with ulcers and lesions. As this is not an obligate parasite, these injuries can be gateways to secondary infections, so these mortalities are most often associated with secondary infections caused by bacteria [12] [13] . Epistylis spp. commonly colonizes planktonic copepods [14] - [17] . However, colonization studies of ectoparasite crustaceans are rare [11] .

This study describes the first record of Epistylis sp. in Argulus sp. collected from Hoplias aimara, a fish from the upper Araguari River, in the state of Amapá, in the north of Brazil.

2. Materials and Methods

A total of 16 specimens of H. aimara were collected from a stretch of the Araguari River, in the state of Amapá, Brazil (Figure 1), which is the largest river to be truly located in Amapá, being 617 km long. Its source is found in the Parque Nacional Montanhas do Tumucumaque (Tumucumaque Mountains National Park), in the Guiana Shield [18] . It passes through the municipalities of Porto Grande and Ferreira Gomes, in the Floresta Nacional do Amapá (Amapá National Forest) (FLONA), the Floresta Estadual do Amapá (Amapá State Forest) (FLOTA) and the Reserva Biológica do Lago Piratuba (Lake Piratuba Biological Reserve) (REBIO), and there are two hydroelectric power plants along its course.

The collection of H. aimara took place in July 2014, using a hand line and gillnet with different mesh sizes. Immediately after capture, the fish were macroscopically examined for the presence of ectoparasite crustaceans. Then, each fish was weighed (g) and its standard length measured (cm). The crustacean specimens collected were fixed in 70% ethanol before being transferred to 70% glycerinated alcohol after 48 hours (10%) and identified in accordance with [8] . The prevalence values, mean abundance and mean intensity were calculated in accordance with [19] . These procedures were carried out in accordance with the principles of the Colégio Brasileiro de Experimento Animal (the Brazilian College of Animal Experimentation) (COBEA).

For analysis with a scanning electron microscope (SEM), five specimens of Argulus sp. previously fixed in 70% ethanol were transferred to a 2.5% glutaraldehyde solution in 0.15 M phosphate buffer (pH 7.3) for 24 h, and post-fixed in 1% osmium tetroxide in the same buffer for 2 h. Dehydration was performed with an increasing sequence of ethanol solutions, and critical point drying was carried out with a CPD 020 (Union Balzer) with liquid CO2. The specimens were coated with a 20 nm layer of gold using the MED 010 apparatus (Balzer Union). Analysis was performed by SEM (SEM 515 Philips).

3. Results

A total of 16 H. aimara fish with a body weight of 1619.9 ± 1054.7 g and a standard length of 40.7 ± 9.3 cm were collected. From these hosts (n = 15) a total of 73 specimens of Argulus sp. were collected from the pelvic, caudal and pectoral fins and tegument, with a prevalence of 93.7%, average intensity of 4.9 host and mean abundance of 4.6. Of these specimens of Argulus sp. five were infested by Epistylis sp., which were adhered in large quantity to the ventral region of the argulidae (Figure 2).

Figure 1. Geographic location of Hoplias aimara collection area in a stretch of the upper Araguari River, in the state of Amapá, in the north of Brazil.

The specimens of Epistylis sp. established themselves on Argulus sp., which in turn serves as a substrate and means of transport, with no lysis or mechanical injury to the infested Argulus sp. observed. The Argulus sp. were infested by Epistylis sp. in various parts of the bodies, with a stalk bearing several zooids (Figure 2A and Figure 2B). This stalk is relatively long and may be divided to form colonies which can be either longer or shorter or more or less ramified (Figure 2B). The vaulted epistomial disc is slightly elevated above the peristomial lips and slanted. The macronuclei are long (Figure 2D).

4. Discussion

Hoplias aimara was infested by Argulus sp., which is a new species found parasitizing this host from the Araguari River basin in the state of Amapá (eastern Amazon region, Brazil). Different species of Argulus have been found infesting Brazilian fish, especially species of Anostomidae, Pimelodidae, Cichlidae and Serrasalmidae [6] .

Figure 2. A. Scanning Electron Microscopy (SEM) detailing Epistylis sp. adhered to the anterior region of Argulus sp. B. Extensive and ramified colonies of Epistylis sp. adhered to Argulus sp. C. Epistylis sp. D. Vaulted epistomial disc, slightly elevated above peristomial lips.

These ectoparasites are often found parasitizing the lentic fish environment, as natant-free forms can find their host more easily in such an environment [4] [7] [20] . However, in H. aimara we found a high prevalence of Argulus sp., indicating that the infestations also occur in fish from lotic environments, as this host fish also inhabits rapids environments [3] , such as the Rio Araguari, the basin of this study. Additionally, the levels of infestation of Argulus sp. in H. aimara were similar to those of Argulus foliaceus described for Cyprinus carpio and Abramis brama [4] and greater than Argulus pestifer in Pseudoplatystoma faciatum [7] .

Species of Epistylis are not obligate ectoparasites, but live in epibiosis with shellfish, aquatic plants, rotifers, aquatic insects, amphibians, reptiles, free crustaceans and parasitic crustaceans [10] [11] as has been described for the occurrence of Epistylis sp. in Ergasilus chelangulatus from Pimelodus maculatus [11] . In this manner, the results of the present study suggest that Epistylis sp. also colonizes H. aimara, the fish from which specimens of Argulus sp. were collected. Species of Epistylis have been reported in different species of freshwater fish in Brazil, such as Colisa lalia, Ctenopharyngodon idella, Oreochromis niloticus, Piaractus mesopotamicus, Pseudoplatystoma corruscans, Pseudoplatystoma reticulatum, Leiarius marmoratus, Hemisorubim platyrhynchos and Zungaro jahu [10] [21] [22] , which were possibly also infected by crustacean species, suggesting that crustaceans are important for the development and maintenance of the life of Epistylis sp. [11] [14] . Furthermore, it is suggested that the infective forms seek new hosts for the fixation and development of new colonies, such as zooplankton copepods, which can act as vectors or host reservoirs of Epistylis spp., as it is common to find these ciliates fixed on the body surface of copepods [14] - [16] thereby increasing the dissemination of this ciliate.

While Epistylis spp. are considered commensal, this protozoan causes damage such as bodily injury, locomotor disorders, low fertility, reduced competitiveness, increased susceptibility to predation, increased energy demand, faster sinking rates and a decrease in the survival rate to hosts, as well as creating the possibility of bacterial infections [12] - [14] [16] . However, in Argulus sp. parasitizing H. Aymara no injury was found. At the same time, the fixation of Epistylis spp. to fish can result in the proliferation of the parasite, causing depigmentation and injuries to the integument with bleeding issues and the excessive production of mucus, triggering anorexia and itching [21] . Thus, it is suggested that Epistylis spp. is an opportunistic parasite that uses Argulus sp. as a substrate and a means of infecting other animals such as H. aimara, which have a greater area for their proliferation.

This first report of Epistylis sp. on the body surface of Argulus sp., in addition to being the first record of Argulus sp. parasitizing H. aimara, extends the geographical distribution of these two species of ectoparasites to the eastern Amazon region in the extreme north of Brazil.


The authors would like to thank Brazil International Conservation (CI), Walmart Brazil, the Instituto Chico Mendes de Conservação da Biodiversidade (ICMBio), and the Biologia e Etnoecologia da Ictiofauna na Floresta Nacional do Amapá (the Biology and Ethno-ecology of the Ichthyofauna of the Amapa National Forest) (FLONA) project for its support. We would also like to thank the fishermen for their help with specimen collection and the evaluators for suggestions that improved the quality of this manuscript, as well as the National Council for Research and Technological Development (CNPq, Brazil), for the productivity scholarship for Dr. Marcos Tavares-Dias.


*Corresponding author.

Conflicts of Interest

The authors declare no conflicts of interest.


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