Hostname: page-component-586b7cd67f-rdxmf Total loading time: 0 Render date: 2024-11-27T23:05:21.594Z Has data issue: false hasContentIssue false

Species of Ergasilus von Nordmann, 1832 (Copepoda: Ergasilidae) from cichlid fishes in Lake Tanganyika

Published online by Cambridge University Press:  20 March 2023

Robert Míč*
Affiliation:
Department of Botany and Zoology, Faculty of Science, Masaryk University, Kotlářská 2, 611 37, Brno, Czech Republic
Eva Řehulková
Affiliation:
Department of Botany and Zoology, Faculty of Science, Masaryk University, Kotlářská 2, 611 37, Brno, Czech Republic
Mária Seifertová
Affiliation:
Department of Botany and Zoology, Faculty of Science, Masaryk University, Kotlářská 2, 611 37, Brno, Czech Republic
*
Author for correspondence: Robert Míč, E-mail: [email protected]

Abstract

Ergasilus (von Nordmann, 1832) (Ergasilidae) is a species-rich group of parasitic copepods with a wide distribution in freshwater, marine and brackish environments. Up to now, 9 species of Ergasilus are known from cichlid fishes in Africa. In this study, 5 species, including 3 new, were collected from the gills of 12 cichlid species (11 genera: Bathybates, Ctenochromis, Eretmodus, Gnathochromis, Lamprologus, Neolamprologus, Ophthalmotilapia, Perissodus, Simochromis, Spathodus and Tanganicodus) of the northeastern shore of Lake Tanganyika in Burundi, namely E. macrodactylus (Sars, 1909), E. megacheir (Sars, 1909), E. caparti n. sp., E. parasarsi n. sp. and E. parvus n. sp. All species found were identified and described on the basis of adult female specimens using an integrative taxonomy approach mixing morphological characterization and molecular analyses of 2 ribosomal DNA markers (partial 18S and 28S rDNA sequences). An identification key for Ergasilus species from Lake Tanganyika is included. This study provides the first molecular data for Ergasilus species in Africa. The phylogenetic analyses suggest that the Ergasilus species parasitizing Lake Tanganyikan cichlids form a well-supported clade within the Ergasilidae. However, their phylogenetic relationships with other congeners still remain unclear due to a lack of molecular data for this diverse genus.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press

Introduction

Lake Tanganyika, one of the largest (32 900 km2) tropical lakes and the oldest (~9–12 Ma) of the East African Great Lakes (Cohen et al., Reference Cohen, Soreghan and Scholz1993), represents a unique freshwater ecosystem characterized by high levels of species richness and a high degree of endemism. Therefore, it has received an intensive interest from scientists of various fields for decades (e.g. Kmentová et al., Reference Kmentová, van Steenberge, Raeymaekers, Koblmüller, Hablützel, Bukinga, N'sibula, Mulungula, Nzigidahera, Ntakimazi, Gelnar and Vanhove2018; Rahmouni et al., Reference Rahmouni, Vanhove and Šimková2018; Koblmüller et al., Reference Koblmüller, Zangl, Börger, Daill, Vanhove, Sturmbauer and Sefc2019; Ryan et al., Reference Ryan, Soreghan, McGlue, Todd, Michel, Kaufman and Kimirei2020; Ivory et al., Reference Ivory, McGlue, Peterman, Baldwin, Lucas, Cohen, Russell, Saroni, Msaky, Kimirei and Soreghan2021). In this respect, cichlids (Cichlidae) have become one of the most studied model systems in the research on evolutionary processes, speciation events (e.g. Hayward et al., Reference Hayward, Tsuboi, Owusu, Kotrschal, Buechel, Zidar, Cornwallis, Løvlie and Kolm2017; Irisarri et al., Reference Irisarri, Singh, Koblmüller, Torres-Dowdall, Henning, Franchini, Fischer, Lemmon, Lemmon, Thallinger, Sturmbauer and Meyer2018; Fischer et al., Reference Fischer, Koblmüller, Börger, Michelitsch, Trajanoski, Schlötterer, Guelly, Thallinger and Sturmbauer2021) and behavioural biology (e.g. Raffini et al., Reference Raffini, Fruciano and Meyer2018; Satoh et al., Reference Satoh, Ota, Awata and Kohda2019, Reference Satoh, Saeki, Kohda and Awata2022). Currently, 240 valid cichlid species belonging to 52 genera and 13 tribes are described from Lake Tanganyika; all (except 2 species) are endemic to the basin (Ronco et al., Reference Ronco, Matschiner, Böhne, Boila, Büscher, el Taher, Indermaur, Malinsky, Ricci, Kahmen, Jentoft and Salzburger2021) and comprise the morphologically, behaviourally and ecologically most diverse species assemblage (Snoeks, Reference Snoeks2000). It is not surprising then that cichlid fishes have also become a suitable model for studies of host–parasite systems. In recent years, the most studied fish parasites from Lake Tanganyika have been, in particular, Monogenea (e.g. Vanhove et al., Reference Vanhove, Pariselle, van Steenberge, Raeymaekers, Hablützel, Gillardin, Hellemans, Breman, Koblmüller, Sturmbauer, Snoeks, Volckaert and Huyse2015; Rahmouni et al., Reference Rahmouni, Vanhove and Šimková2017, Reference Rahmouni, Vanhove and Šimková2018), in contrast to parasitic crustaceans that have been neglected for decades, not only in Lake Tanganyika but in Africa overall (Scholz et al., Reference Scholz, Vanhove, Smit, Jayasundera and Gelnar2018).

Ergasilus (von Nordmann, 1832) represents the type and most speciose genus of the family Ergasilidae (Burmeister, 1835), with approximately 160 nominal species worldwide, inhabiting fresh, marine and brackish waters (Boxshall and Defaye, Reference Boxshall, Defaye, Balian, Lévêque, Segers and Martens2007; WoRMS Editorial Board, 2022). In recent years, the majority of systematic studies dealing with ergasilid species originated from the Neotropical region (Marques et al., Reference Marques, Boeger and de Carvalho Brasil-Sato2015; Muriel-Hoyos et al., Reference Muriel-Hoyos, Santana-Piñeros, Cruz-Quintana and Suárez-Morales2015; Taborda et al., Reference Taborda, Paschoal and Luque2016; Varella et al., Reference Varella, Morey and de Oliveira Malta2019; Narciso et al., Reference Narciso, Brandão, Perbiche-Neves and da Silva2020; Santacruz et al., Reference Santacruz, Morales-Serna, Leal-Cardín, Barluenga and Pérez-Ponce de León2020; Waicheim et al., Reference Waicheim, Mendes Marques, Rauque and Viozzi2021), which is in contrast to Africa, where no new records have been available in the past few decades. The first studies of African Ergasilidae were conducted between 1900 and 1928 in the African Great Lakes (Sars, Reference Sars1909; van Douwe, Reference van Douwe1912; Cunnington, Reference Cunnington1920; Gurney, Reference Gurney1928), while the first description of Ergasilus species from Africa was made by Sars (Reference Sars1909), who described 3 species (originally assigned to the currently invalid genus Ergasiloides) from Lake Tanganyika. From the 1920s to the late 1960s, the next occurrences of Ergasilus species were reported in large African river systems such as the Niger River (Capart, Reference Capart1956), the Volta (Paperna, Reference Paperna1969), the Congo (Fryer, Reference Fryer1963, Reference Fryer1967), the White Nile (Wilson, Reference Wilson and Jägerskiöld1924) and the lakes (Albert, Edward, Kivu, Malawi, Rudolf, Tanganyika and Victoria) (Fryer, Reference Fryer1956, Reference Fryer1960, Reference Fryer1961, Reference Fryer1965). To date, 11 valid species of Ergasilus are described from the gills of 13 families of freshwater fishes from Africa, 5 of them recorded on cichlids, mochokids and poeciliids from Lake Tanganyika: E. flaccidus Fryer, Reference Fryer1965; E. kandti van Douwe, 1912; E. macrodactylus (Sars, Reference Sars1909); E. megacheir (Sars, Reference Sars1909); and E. sarsi Capart, Reference Capart1944 (Sars, Reference Sars1909; Cunnington, Reference Cunnington1914; Capart, Reference Capart1944; Fryer, Reference Fryer1965; Oldewage and van As, Reference Oldewage and van As1988; Kilian and Avenant-Oldewage, Reference Kilian and Avenant-Oldewage2013; Smit and Hadfield, Reference Smit and Hadfield2018). However, since Fryer's research (Reference Fryer1965, Reference Fryer1968), records of ergasilids from Lake Tanganyika are scarce. Kondo and Hori (Reference Kondo and Hori1986) and Raeymaekers et al. (Reference Raeymaekers, Hablützel, Grégoir, Bamps, Roose, Vanhove, van Steenberge, Pariselle, Huyse, Snoeks and Volckaert2013) reported unidentified species of the genus Ergasilus in the southern end of Lake Tanganyika, but no morphological determination was provided in either of the studies. The last study that included ergasilids from Tanganyika was by Kilian and Avenant-Oldewage (Reference Kilian and Avenant-Oldewage2013) that reported the first record of E. sarsi from Tanganyika killifish and provides a description of the pathological alterations caused by this species. Nevertheless, over the last 30 years, the interest in Ergasilidae in Africa has declined. This suggests that the ergasilid fauna in Africa is still largely underexplored and that its intensive investigation is therefore needed.

Moreover, all previous records of Ergasilus species are based solely on morphometric data. Until recently, the majority of available molecular data for Ergasilus came from Song et al. (Reference Song, Wang, Yao, Gao and Nie2008), who provided the first phylogenetic analysis of the family Ergasilidae (comprising 14 species collected in China) and proposed a polyphyletic origin for this genus. Molecular data for the African ergasilids are still completely lacking. Such data would help to resolve the taxonomical and phylogenetic relationships poorly known in this highly diverse parasitic group.

During our parasitological survey of metazoan parasites of cichlids from Lake Tanganyika, we recovered 2 previously described and 3 new Ergasilus species. All species found were described using a combined morphological and molecular approach as an integrative taxonomy, a recent trend that promises to complete dubious and precise descriptions and other taxonomic problems. Additionally, the phylogenetic relationships among ergasilids from Lake Tanganyika cichlids were investigated on the basis of rDNA sequence data (partial 18S and 28S rDNA).

Materials and methods

Fish collection

During a parasitological survey in 2013, 23 species (167 specimens) of cichlid fishes, representing 11 tribes, were bought from a local fish market in Bujumbura (3°23′S, 29°22′E) or obtained from commercial fishermen fishing in 4 localities on the northeastern shore of Lake Tanganyika in Burundi: (1) Magara (3°44′S, 29°19′E); (2) Mukuruka (4°14′S, 29°33′E), (3) Mvugo (4°15′S, 29°34′E) and (4) Nyaruhongoka (3°41′S, 29°20′E) (Fig. 1, Table 1). The determination of cichlid hosts was provided by Dr Stephan Koblmüller (The University of Graz, Austria) using the keys of Takahashi (Reference Takahashi2003) and Takahashi and Koblmüller (Reference Takahashi and Koblmüller2011). Live fish specimens were killed by severing the spinal cord and were subsequently processed for parasitological examination. The scientific names of fish hosts follow Froese and Pauly (Reference Froese and Pauly2022).

Fig. 1. Map of Lake Tanganyika indicating the sampling localities along the northeastern shore in Burundi: (1) Magara; (2) Mukuruka; (3) Mvugo; (4) Nyaruhongoka.

Table 1. List of all sampled fishes and their sampling localities

Parasitized fishes are highlighted in bold, localities on which the host was parasitized by Ergasilus is marked with the symbol*.

Parasite collection and identification

The body surface, gills and nasal cavities of freshly killed fishes were examined for the presence of parasitic copepods using a dissecting microscope. Live copepods were collected from the gills using fine needles and were fixed in 70% ethanol for later morphological examination, or in 96% ethanol for molecular analysis. In addition, a subset of specimens collected for DNA analyses were dissected and the egg sac or a small part of the body were cut off using fine needles under a dissecting microscope and used for DNA extraction; the rest of the body was used for morphological evaluation as hologenophore. For the morphological determination of copepods, specimens were placed on a microscopic slide in a drop of water with lactic acid to clear and soften them. The selected crustaceans were then fixed in pure glycerine (Dávidová and Smit, Reference Dávidová and Smit2018) or glycerine ammonium picrate and examined. The mounted specimens were studied using an Olympus BX61 microscope equipped with phase-contrast optics. Drawings of the copepods were made using an Olympus drawing attachment and edited with a graphic tablet (Wacom Intuos5 Touch) compatible with Adobe Illustrator and Adobe Photoshop (Adobe Systems Inc., San Jose, CA, USA). All measurements (in micrometres) were taken using a digital image analysis software (Olympus Stream Motion v. 1.9.3) and are presented as mean followed by range and number (n) of specimens measured in parentheses. Ergasilus species were determined according to Oldewage and van As (Reference Oldewage and van As1988) on the basis of the shape and size of the body, the antennae, the antennules, the cephalothorax, pigmentation, the setae and spines on legs I–IV, rudimentary leg V, the genital somite, the furcal rami and the shape of the egg sac. Morphological terminology follows that of Huys and Boxshall (Reference Huys and Boxshall1991).

For comparative purposes, specimens of the following 7 previously described species of Ergasilus from the Natural History Museum (London, UK; BMNH) and Royal Belgian Institute of Natural Sciences (Bruxelles, Belgium; RBINS COP) were examined:

E. cunningtoni Capart, Reference Capart1944 (BMNH 1950.7.29.23); E. flaccidus Fryer, Reference Fryer1965 (BMNH 1965.10.6.1); E. kandti Douwe, 1912 (BMNH 1998.929-930); E. lamellifer Fryer, Reference Fryer1961 (BMNH 1998.931); E. latus Fryer, Reference Fryer1960 (BMNH 1993.122-131); E. macrodactylus (Sars, Reference Sars1909) (COP 6086, COP 6087, COP 6088, COP 6089); and E. sarsi Capart, Reference Capart1944 (COP 0493, COP 0494).

The type and voucher specimens of the copepods collected in the present study were deposited in the Institute of Parasitology, Czech Academy of Sciences, České Budějovice, Czech Republic. Prevalence (percentage of infected fish) and mean intensity of infection (mean number of parasites per infected host) were calculated for each Ergasilus species found following Bush et al. (Reference Bush, Lafferty, Lotz and Shostak1997).

Molecular and phylogenetic analyses

Genomic DNA was isolated separately from each parasite specimen (or its part) using DNeasy®Blood & Tissue Kit (Qiagen, Hilden, Germany) according to the manufacturer's instructions. To perform molecular characterization of the species found and to elucidate their phylogenetic position within Ergasilidae, 2 ribosomal nuclear fragments (18S rDNA and 28S rDNA) were analysed. Partial 28S rDNA fragment was amplified using primers 28SF (forward, 5′-ACA ACT GTG ATG CCC TTA G-3′) and 28SR (reverse, 5′-TGG TCC GTG TTT CAA GAC G-3′) (Song et al., Reference Song, Wang, Yao, Gao and Nie2008). Primers 18SF (forward, 5′-AAG GTG TGM CCT ATC AAC T-3′) (Song et al., Reference Song, Wang, Yao, Gao and Nie2008) and 18SR (reverse, 5′-TTA CTT CCT CTA AAC GCT C-3′) (Song et al., Reference Song, Wang, Yao, Gao and Nie2008) were used for amplification of the partial fragment of 18S rDNA. In addition, the newly designed primers Erg18SF1 (forward, 5′-ATT GGA GGG CAA GTC TGG TG-3′), Erg18SF2-int (forward, 5′-CGA TCA GAT ACC GCC CTA GT-3′) and Erg18SR2 (reverse, 5′-AAG GGC AGG GAC GTA ATC AA-3′) were used for amplifications of the 18S rDNA fragment when the first combination of primers failed. All PCRs were carried out in a total volume of 20 μL containing 3 μL of DNA extract, 1× PCR buffer (Fermentas, Waltham, MA, USA), 2 mm MgCl2, 200 μ m of each dNTP, 0.2 μ m of each primer and 1 U of Taq polymerase (Fermentas). Amplification was performed under the following conditions: 94°C for 5 min; 39 cycles of 94°C for 30 s; an annealing temperature of 54°C for 30 s; and 72°C for 1 min, with a final extension step at 72°C for 5 min. The PCR amplicons were checked by electrophoresis on 1.5% agarose gels stained with GoodView™ (Amplia s.r.o., Bratislava, Slovakia), and PCR products of the required length were purified using ExoSAP-IT™ (Affymetrix Inc., Santa Clara, USA), following the manufacturer's instructions. Purified products were directly sequenced using the same primers as those for PCR. DNA sequencing was carried out using BigDye® Terminator v3.1 Cycle Sequencing Kit (Applied Biosystems by Thermo Fisher Scientific, Prague, Czech Republic) and a 3130 Genetic Analyzer (Applied Biosystems). The obtained sequences were assembled and edited using Sequencher software (Gene Codes Corp., Ann Arbor, MI, USA). Newly generated sequences for each species were deposited in GenBank under accession numbers OQ407470–OQ407474 (28S rDNA) and OQ407465–OQ407469 (18S rDNA), and molecular vouchers (hologenophores, paragenophores; Pleijel et al., Reference Pleijel, Jondelius, Norlinder, Nygren, Oxelman, Schander, Sundberg and Thollesson2008) were deposited in the Institute of Parasitology, Czech Academy of Sciences, České Budějovice, Czech Republic.

To investigate the phylogenetic position of copepods of Lake Tanganyika cichlids, relevant available sequences of Ergasilidae from 5 genera were retrieved from GenBank (for details, see Table 2). Three species of the family Lernaeidae, Lernaea cyprinacea (Linnaeus, 1758), Lamproglena chinensis (Yü, 1937) and Lamproglena orientalis (Markevich, 1936) were selected as outgroup. Partial sequences of 18S rDNA and 28S rDNA were aligned separately using MAFFT v.7 (Katoh and Standley, Reference Katoh and Standley2013), applying the G-INS-i iterative refinement algorithm. Gaps and ambiguously aligned regions were removed from the alignments with Gblocks v0.91b (Talavera and Castresana, Reference Talavera and Castresana2007) using settings for a less stringent selection. jModelTest 2.1.10 (Darriba et al., Reference Darriba, Taboada, Doallo and Posada2012) was employed to select the most appropriate model of DNA evolution, using the Bayesian information criterion for each individual gene. The most suitable evolutionary model was TIM3e + I + G for the partial gene encoding 18S rRNA and TIM3 + F + I + G for the partial gene of 28S rRNA. The final phylogenetic reconstruction was performed on the concatenated dataset including partial 18S rDNA (991 bp) and partial 28S rDNA (588 bp) using maximum likelihood (ML) and Bayesian inference (BI) methods. ML analyses were carried out using IQ-TREE (Nguyen et al., Reference Nguyen, Schmidt, von Haeseler and Minh2015) on the W-IQ-TREE webserver (Trifinopoulos et al., Reference Trifinopoulos, Nguyen, von Haeseler and Minh2016) and nodal support for the tree was assessed through ultrafast bootstrap approximation with 1000 replicates (Hoang et al., Reference Hoang, Chernomor, von Haeseler, Minh and Vinh2018). BI analysis was run in MrBayes 3.2.6 (Huelsenbeck and Ronquist, Reference Huelsenbeck and Ronquist2001) using the CIPRES platform (Miller et al., Reference Miller, Pfeiffer and Schwartz2010), by setting the GTR + F + I (nst = 6 rates = invgamma) model for each partition; the analysis included 2 simultaneous runs of Markov chain Monte Carlo for 10 000 generations, sampling every 100 generations, with a ‘burn-in’ of 25%. The results were checked in Tracer v. 1.7.1 (Rambaut et al., Reference Rambaut, Drummond, Xie, Baele and Suchard2018) to assess chain convergence. The trees were visualized and edited in FigTree v1.4.3 (Rambaut, Reference Rambaut2012). Genetic distances (uncorrected p-distance) were calculated in MEGA v.11 (Tamura et al., Reference Tamura, Stecher and Kumar2021).

Table 2. List of parasitic copepods used for phylogenetic analysis, including their host species, collection locality and accession numbers for partial 18S and 28S rDNA sequences

Newly generated sequences are given in bold.

Results

The gill-associated parasitic copepods were obtained from 12 species of cichlids inhabiting Lake Tanganyika. All specimens were assigned to Ergasilus on the basis of several diagnostic characters, according to Boxshall and Montú (Reference Boxshall and Montú1997); Boxshall and Halsey (Reference Boxshall and Halsey2004); Suárez-Morales and Santana-Piñeros (Reference Suárez-Morales and Santana-Piñeros2008). These included (i) biramous leg IV with 2-segmented exopod and 3-segmented endopod, (ii) 6-segmented antennule, (iii) antenna with a single claw and (iv) the absence of maxillipeds in females. Three new and 2 previously described species of Ergasilus are figured and described below.

Species richness of Ergasilus parasites on the host species investigated ranged from 1 to 4. Bathybates ferox and Ctenochromis horei were each found to harbour 1 Ergasilus species (i.e. E. megacheir and E. parvus n. sp., respectively). Eretmodus marksmithi and Lamprologus callipterus were each found to be hosts of 4 Ergasilus species (i.e. E. caparti n. sp., E. macrodactylus, E. parasarsi n. sp. and E. parvus n. sp.). The number of host species ranged from 2 for E. megacheir to a maximum of 7 for E. parvus n. sp. (Table 3). The highest prevalence (100%) was observed for E. macrodactylus on Gnathochromis permaxillaris and Perissodus microlepis, as well as for E. parvus n. sp. on B. ferox (only 1 specimen examined). The highest intensity of infection (62 individuals) was observed for E. caparti n. sp. on E. marksmithi (for detailed information see Table 3).

Table 3. Prevalence (first line), mean intensity of infection (second line) and intensity of infection (min–max; third line) of 5 Ergasilus species from Lake Tanganyika found on 12 cichlid host species (n = total number of host specimens examined)

Family Ergasilidae (Burmeister, 1835)

Genus Ergasilus (von Nordmann, 1832)

Ergasilus macrodactylus (Sars, Reference Sars1909)

Syn. Ergasiloides macrodactylus (Sars, Reference Sars1909)

Type-host: not recorded.

Type locality: Lake Tanganyika, Sumbu, Zambia.

Site on host: gill filaments.

Other previous records: Brycinus imberi (Peters, 1852) (Characiformes: Alestidae), Haplochromis spp., Lethrinops spp., Pseudotropheus spp., Tilapia spp. (Cichliformes: Cichlidae), Lake Malawi, Malawi (Fryer, Reference Fryer1956).

Present records: E. marksmithi (localities 1, 2, 4); G. permaxillaris (locality 2); L. callipterus (localities 2, 4); P. microlepis (locality 4); Tanganicodus irsacae (locality 2) (see Table 1).

Comparative material examined: four voucher specimens of E. macrodactylus (Sars, Reference Sars1909) from Haplochromis spp. (Malawi): RBINS COP 6086, 6087, 6088 and 6089.

Voucher material deposited: Cr-33 (2 specimens, locality 2); hologenophore: Cr-33 (3 specimens, locality 2).

Representative DNA sequences: 18S rDNA (GenBank acc. no. OQ407465) and 28S rDNA (GenBank acc. no. OQ407470) (see also Table 2) sequences from 5 specimens ex E. marksmithi (n = 1), G. permaxillaris (n = 3) and P. microlepis (n = 1).

Description

Adult female [based on 10 specimens; Figs 2 and 3]. Body length (measured from anterior margin of prosome to posterior margin of caudal rami) 659 (554–864; n = 10). Body comprising prosome and urosome (Fig. 2A). Prosome 5-segmented, composed of cephalosome and 4 pedigerous somites; cephalosome and first pedigerous somite separate.

Fig. 2. Ergasilus macrodactylus, adult female from Gnathochromis permaxillaris. (A) Habitus, dorsal; (B) antenna, ventral; (C) mandible and maxilulle, ventral; (D) maxilla, ventral; (E) antennule, ventral; (F) abdomen and caudal rami; (G) egg sac, dorsal; (H) leg V, ventral.

Fig. 3. Ergasilus macrodactylus, adult female from Gnathochromis permaxillaris. (A) Leg I, ventral; (B) leg II, ventral; (C) leg III, ventral; (D) leg IV, ventral.

Cephalosome trapezoidal, with truncate frontal margin and distinctly projecting postero-lateral corners; antennules and antennae visible in dorsal view. Cephalic ornamentation comprising anterior and posterior circular markings of similar sizes; an inverted T-structure of thickened chitin situated postmedially on dorsal side. Eye spot clearly visible near anterior margin of cephalosome. Four pedigerous somites evenly rounded at lateral margins, decreasing in length and width posteriorly.

Urosome narrow, comprising short fifth pedigerous somite, genital segment (Fig. 2F), and 3 free abdominal somites. Genital segment barrel-shaped, posteriorly tapered, with dorsal bilateral cuticular ornamentation. Abdominal somites slightly decreasing in width posteriorly; third abdominal somite slightly incised medially.

Caudal rami with subrectangular shape, slightly longer than wide, posteriorly widening; each ramus armed with 4 terminal setae – the innermost furcal seta at least 5 times longer than others, slightly swollen near the basis and directed outwards. Two egg sacs (Fig. 2G), much longer than wide; each composed of 2–3 rows of circular-shaped eggs and reaching beyond the longest furcal setae.

Antennule (Fig. 2E) 6-segmented; segments well defined and tapering distally, armed with simple setae; setal formula from proximal to distal segments: 4–7–6–3–2–4.

Antenna (Fig. 2B) comprising short coxobasis, 3-segmented endopod and curved terminal claw. First endopod segment twice as long as the coxobasis and attenuated distally; no hyaline border present. Second endopod segment elongated, slightly corrugated in its proximal third. Third endopodal segment small. Terminal claw very slender, pointed and smooth. Antenna without setules or spines.

Mouthparts comprising mandible, maxillule and maxilla; maxilliped absent. Mandible consisting of 3 blades (anterior, middle and posterior); each blade with small teeth on anterior margin (Fig. 2C). Maxillule a small single lobe, with 2 almost equally long distal setae. Maxilla 2-segmented, with numerous sharp teeth on anterior margin of distal segment (Fig. 2D).

Swimming legs I to IV; each comprising coxa, basis and 2 segmented rami (i.e. exopod, endopod) (Fig. 3). Rami of all legs 3-segmented, except 2-segmented exopod of leg IV. Segments distinct, typical of members of the genus. Interpodal plates of all legs lacking spinules. Armature on rami as follows (Roman and Arabic numerals indicating spines and plumose setae, respectively) in Table 4.

Table 4. Spine and setal formula of swimming legs of E. macrodactylus

Leg I (Fig. 3A) coxa unarmed, basis with outer seta. Exopod 3-segmented; first segment with small outer spine; second segment with inner plumose seta and a small outer spine; third segment with small spine on outer corner, longer apical spine and 5 plumose setae. Endopod 3-segmented; first and second segment each with 1 plumose seta; third segment with 4 plumose setae and 2 distal spines.

Leg II (Fig. 3B) coxa unarmed, basis with outer seta. Exopod 3-segmented; first segment with very small outer spine; second segment with 1 plumose seta, lacking spine; third segment with 6 plumose setae. Endopod 3-segmented; first segment with 1 plumose seta; second segment with 2 plumose setae; third segment with 4 plumose setae and 1 distal spine.

Leg III (Fig. 3C) coxa unarmed, basis with outer seta. Exopod 3-segmented; first segment lacking armature; second segment with 2 plumose setae; third segment with 4 plumose setae and 1 distal spine. Endopod 3-segmented; first segment with 1 plumose seta; second segment with 2 plumose setae; third segment with 4 plumose setae and 1 distal spine.

Leg IV (Fig. 3D) coxa unarmed, basis with outer seta. Exopod 2-segmented; first segment longest and without armature; second segment with 5 plumose setae. Endopod 3-segmented; first and second segment each with 1 plumose seta; third segment with 3 plumose setae and 1 distal spine.

Leg V (Fig. 2H) simple and visible, with cylindrical form, bearing 2 terminal simple seta.

Specimens preserved in ethanol rather light in colour; traces of a purple pigment in cephalothorax observed after clearing in lactic acid.

Male: unknown.

Remarks

Ergasilus macrodactylus is characterized, in part, by having trapezoidal cephalothorax, elongate antenna and clearly visible eye spot (Fryer, Reference Fryer1956). Based on the overall body shape, this species is similar to E. megacheir but clearly differs from it by having: (i) 3-segmented abdomen; (ii) the first endopod segment of the antenna without hyaline border on anterior edge; (iii) elongate and distally recurved second endopod segment of the antenna (second endopod segment short and twisted in E. megacheir); (iv) the terminal claw of the antenna with smooth margins (claw with inner denticle in E. megacheir); (v) a tiny spine on the first segment of the exopod of leg II; (vi) 2 plumose setae on the second segment of the endopods of leg II and III (1 plumose seta on the respective endopods in E. megacheir); and (vii) a different spine–seta formula on the exopod of leg III (0–0, 0–2, I–4 vs 0–0, 0–1, 0–6 in E. megacheir).

Ergasilus macrodactylus was a cause of much confusion in the past. This species has been described as Ergasiloides macrodactylus (Sars, Reference Sars1909), and later transferred to Ergasilus by Fryer (Reference Fryer1956), when he found specimens conspecific with E. macrodactylus in Lake Malawi. According to Fryer (Reference Fryer1956), Sars (Reference Sars1909) was wrong when he based the description of his species on immature specimens, and therefore wrongly placed it in Ergasiloides. Although E. macrodactylus was already reported in Lake Tanganyika by Sars (Reference Sars1909), it was omitted from the checklist for parasites from Lake Tanganyika (Avenant-Oldewage and Oldewage, Reference Avenant-Oldewage and Oldewage1993). Our findings confirm the presence of E. macrodactylus in Lake Tanganyika, even though the overall body size of our specimens is slightly smaller than those of Fryer (Reference Fryer1956) (i.e. 659 vs 765). In this respect, our specimens of E. macrodactylus are more similar to those of Sars (Reference Sars1909).

Ergasilus megacheir (Sars, Reference Sars1909)

Syn. Ergasiloides megacheir (Sars, Reference Sars1909)

Type-host: not recorded.

Type-locality: Lake Tanganyika, Sumbu, Zambia.

Site on host: gill filaments.

Other previous records: Pterochromis congicus (Boulenger, 1897) (Cichliformes: Cichlidae), Lake Tumba, Congo System (Fryer, Reference Fryer1964); Bathybates minor (Boulenger, 1906), Bathybates fasciatus (Boulenger, 1901), Cyphotilapia frontosa (Boulenger, 1906), Haplotaxodon microlepis (Boulenger, 1906), Limnotilapia dardenii (Boulenger, 1899), Pseudosimochromis curvifrons (Poll, 1942) (Cichliformes: Cichlidae), Synodontis multipunctatus (Boulenger, 1898), Synodontis granulosus (Boulenger, 1900) (Siluriformes: Mochokidae), Lake Tanganyika (Fryer, Reference Fryer1965); Simochromis sp. (Cichliformes: Cichlidae), Lake Tanganyika (Capart, Reference Capart1944); unknown hosts, Lake Tanganyika (Sars, Reference Sars1909; Cunnington, Reference Cunnington1920).

Present records: ex C. horei (locality 4); Simochromis diagramma (locality 1) (see Table 1).

Voucher material deposited: Cr-34 (1 specimen, locality 1); hologenophore: Cr-34 (1 specimen, locality 1).

Representative DNA sequences: 18S rDNA (GenBank acc. no. OQ407466) and 28S rDNA (GenBank acc. no. OQ407471) (see also Table 2) sequences from 2 specimens ex S. diagramma.

Description

Adult female [based on 5 specimens; Figs 4 and 5]. Body length (measured from anterior margin of prosome to posterior margin of caudal rami) 698 (613–770; n = 5). Prosome 5-segmented, composed of cephalosome and 4 pedigerous somites; cephalosome and first pedigerous somite separate (Fig. 4A). Cephalosome quadrangular, frontal edge truncated, postero-lateral corners slightly prominent and rounded; antennules and antennae visible in dorsal view. Cephalic ornamentation comprising anterior ovoid marking and posterior oval marking; an inverted T-structure of thickened chitin situated postmedially on dorsal side, between the circular and oval marking. Eye spot clearly visible near anterior margin of cephalosome. Four pedigerous somites with lateral parts slightly produced backwards, rounded obtusely at the end.

Fig. 4. Ergasilus megacheir, adult female from Simochromis diagramma. (A) Habitus, dorsal; (B) antenna, ventral; (C) mandible and maxilulle, ventral; (D) maxilla, ventral; (E) antennule, ventral; (F) abdomen and caudal rami; (G) egg sac, dorsal; (H) leg V, ventral.

Fig. 5. Ergasilus megacheir, adult female from Simochromis diagramma. (A) Leg I, ventral; (B) leg II, ventral; (C) leg III, ventral; (D) leg IV, ventral.

Urosome small, comprising short fifth pedigerous somite, genital segment (Fig. 4F) and 2 free abdominal somites. Fifth pedigerous somite almost wholly concealed. Genital segment barrel-shaped, anteriorly tapered.

Second abdominal somite shallowly incised medially, much longer than preceding somite. Caudal rami subrectangular, as long as the length of the previous segment; each ramus armed with 4 terminal setae – the innermost longest and thickest; outer setae pointing towards middle body axis.

Two egg sacs (Fig. 4G) much longer than wide; each composed of 2–4 rows of circular-shaped eggs. Some specimen egg sacs extremely long, almost the same length as the whole body.

Antennule (Fig. 4E) 6-segmented; segments well defined, tapering distally, armed with simple setae; setal formula from proximal to distal segments: 4–11–3–4–3–6.

Antenna (Fig. 4B) comprising short coxobasis, 3-segmented endopod, and strongly curved terminal claw. First endopodal segment twice as long as the coxobasis, oblong in form, distally slightly narrowed; anterior edge with visible thin hyaline border not fully extending to the base. Second endopodal segment short and twisted, third endopodal segment inconspicuous. Terminal claw about 1/3 length of second endopodal segment, equipped with a recurved denticle inside. Antenna without setules or spines.

Mouthparts comprising mandible, maxillule and maxilla; maxilliped absent. Mandible consisting of 3 blades (anterior, middle and posterior); each blade with small sharp teeth; anterior and posterior blade with teeth located on anterior margin; middle blade with teeth on posterior margin (Fig. 4C). Maxilulle a small lobe with 2 unequally long distal setae and 2 minute inner setae. Maxilla 2-segmented, comprising unarmed syncoxa and basis, distally with numerous sharp teeth on anterior margin (Fig. 4D).

Swimming legs I–IV; each comprising coxa, basis and 2 segmented rami (i.e. exopod, endopod) (Fig. 5). Rami of all legs 3-segmented, except 2-segmented exopod of leg IV. Segments distinct, typical of members of the genus. Interpodal plates of all legs lacking spinules. Armature on rami as follows (Roman and Arabic numerals indicating spines and setae, respectively) in Table 5.

Table 5. Spine and setal formula of swimming legs of E. megacheir

Leg I (Fig. 5A) coxa unarmed, basis with proximal outer seta. Exopod 3-segmented; first segment with small outer spine; second segment with inner plumose seta and a small outer spine; third segment with small spine on outer corner, longer apical spine and 5 plumose setae. Endopod 3-segmented; first and second segment each with 1 plumose seta; third segment with small spine on outer corner, longer distal spine and 4 plumose setae.

Legs II and III (Fig. 5B and C) similar. Coxa unarmed, basis with proximal outer seta. Exopod with 3 segments; first segment lacking armature; second segment with 1 plumose seta, lacking spine; third segment with 6 plumose setae. Endopod with 3 segments; first and second segment each with 1 plumose seta; third segment with 4 plumose setae and 1 distal spine.

Leg IV (Fig. 5D) coxa unarmed, basis with proximal outer seta. Exopod 2-segmented; first segment longest without armature; second segment with 5 plumose setae. Endopod with 3 segments; first and second segment each with 1 plumose seta; third segment with 3 plumose setae and 1 distal spine.

Leg V (Fig. 4H) extremely small, barely visible, with 1 smooth seta.

Specimens preserved in ethanol brown in colour. No pigment observed after clearing in lactic acid.

Male: unknown.

Remarks

Ergasilus megacheir was already recorded from Lake Tanganyika by Sars (Reference Sars1909), Cunnington (Reference Cunnington1920), Capart (Reference Capart1944) and Fryer (Reference Fryer1965). Fryer (Reference Fryer1964) reported this species also from Lake Tumba in Lower Congo. Ergasilus megacheir is easily distinguished from other congeners by the presence of a denticle on the inner side of the terminal claw of the antenna. The size of the denticle differs, being more prominent in presumably smaller specimens and less visible in bigger specimens, which supports Fryer's (Reference Fryer1965) previous observation. Based on comparative morphology, E. megacheir is most similar to E. macrodactylus. The differentiation of both species is provided in the remarks for the latter species.

Although E. megacheir was the least abundant species in our dataset, its presence in the Lake was reconfirmed after more than 50 year. For the first time, egg sacs were described and drawn. The presence of setae on the basis of legs I–IV was also confirmed. The spine can be seen in the original drawings but did not feature in the spine–seta formula.

Ergasilus caparti n. sp.

Type-host: Neolamprologus brichardi (Poll, 1974).

Type-locality: Magara (3°44′S, 29°19′E), Lake Tanganyika, Burundi.

Other hosts and localities: E. marksmithi (localities 1, 2), L. callipterus (locality 4), Neolamprologus mondabu (locality 3), P. microlepis (locality 1), Spathodus erythrodon (locality 1) (see Table 1).

Type and voucher material: holotype (adult female): (Cr-35) ex N. brichardi; paratypes (adult females): Cr-35 ex E. marksmithi; hologenophores (adult females): Cr-35 ex S. erythrodon and E. marksmithi.

Site on host: gill filaments.

ZooBank registration: urn:lsid:zoobank.org:act:7211AE50-81DA-4F73-BE5E-26611C2974C4

Representative DNA sequences: 18S rDNA (GenBank acc. no. OQ407469) and 28S rDNA (GenBank acc. no. OQ407474) (see also Table 2) sequences from 5 specimens ex E. marksmithi (n = 1), L. callipterus (n = 1), N. mondabu (n = 1) and S. erythrodon (n = 2).

Etymology: This species is named after André Capart (1917–1993), director of the Royal Institute of Natural Sciences (Belgium), to honour his contributions to knowledge of the crustacean fauna that resulted from expeditions to the African Great Lakes including Lake Tanganyika (1946–1947).

Description

Adult female [based on 10 specimens; Figs 6 and 7]. Body length (measured from anterior margin of prosome to posterior margin of caudal rami) 509 (411–611; n = 10). Prosome 5-segmented, composed of cephalosome and 4 pedigerous somites; cephalosome and first pedigerous somite separate. Cephalosome hexagonal, with a medial indentation on posterior margin; antennules and antennae visible in dorsal view (Fig. 6A). Cephalic ornamentation comprising anterior circular marking and a more posterior, slightly larger oval marking; an inverted T-structure of thickened chitin situated medially on dorsal side, between the circular and oval marking. First pedigerous somite of similar size as cephalosome, slightly tapering medially. Second to fourth pedigerous somites each markedly narrowing posteriorly.

Fig. 6. Ergasilus caparti n. sp., adult female from Neolamprologus brichardi. (A) Habitus, dorsal; (B) antenna, ventral; (C) mandible and maxilulle, ventral; (D) maxilla, ventral; (E) antennule, ventral; (F) abdomen and caudal rami; (G) egg sac, dorsal; (H) leg V, ventral.

Fig. 7. Ergasilus caparti n. sp., adult female from Neolamprologus brichardi. (A) Leg I, ventral; (B) leg II, ventral; (C) leg III, ventral; (D) leg IV, ventral.

Urosome comprising short fifth pedigerous somite, genital segment (Fig. 6F), and 2 free abdominal somites. Genital segment of similar shape to the first pedigerous somite, slightly widening in posterior half, ventral surface ornate with spinules along postero-ventral margin. Two free abdominal somites with a row of acute spinules along posterior margin on ventral surface. First abdominal somite short, slightly longer than the fifth pedigerous somite. Second abdominal somite deeply incised medially, slightly larger than the preceding somite.

Caudal rami subrectangular, slightly longer than wide; each ramus bearing 4 terminal setae – the innermost longest and thickest but not exceeding egg sacs. Two egg sacs (Fig. 6G) quite long and narrowing distally; each composed of 2–4 rows of eggs.

Antennule (Fig. 6E) 6-segmented, tapering distally, armed with simple setae; setal formula from proximal to distal segments: 2–10–3–3–2–4.

Antenna (Fig. 6B) comprising short coxobasis, 3-segmented endopod and strongly curved terminal claw. First endopodal segment longest; second endopodal segment proximally with conspicuous indentation of cuticle on outer side, formed by 2 ridges crossing each other. Third endopodal segment small, but more conspicuous under the light microscope than in other species from Lake Tanganyika. Terminal claw about 1/3 length of the second endopodal segment. Antenna without setules or spines.

Mouthparts (Fig. 6C and D) comprising mandible, maxilulle and maxilla; maxilliped absent. Mandible consisting of 3 blades (anterior, middle and posterior); anterior blade with sharp teeth on anterior margin; middle and posterior blade with teeth along posterior margin. Maxilulle a well-developed lobe, bearing 2 almost equally long smooth setae. Maxilla 2-segmented, comprising unarmed syncoxa and basis, distally with numerous sharp teeth on anterior margin.

Swimming legs I–IV; each comprising coxa, basis and 2 segmented rami (i.e. exopod, endopod) (Fig. 7). Rami of all legs 3-segmented, except 2-segmented exopod of leg IV. Segments distinct, typical of members of the genus. Interpodal plates of all legs lacking spinules. Armature on rami as follows (Roman and Arabic numerals indicating spines and setae, respectively) in Table 6.

Table 6. Spine and setal formula of swimming legs of E. caparti n. sp.

Leg I (Fig. 7A) coxa unarmed, basis with proximal outer seta. Exopod 3-segmented; first segment lacking armature; second segment with inner plumose seta and a small outer spine; third segment with small spine on outer corner, longer apical spine and 5 plumose setae. Endopod 3-segmented; first segment lacking armature; second segment with 1 plumose seta; third segment with 4 plumose setae and 2 distal spines. Outer margins of both rami partly or completely covered with rows of spinules.

Legs II and III similar (Fig. 7B and C). Coxa unarmed, basis with proximal outer seta. Exopod 3-segmented; first segment lacking armature; second segment with 1 plumose seta, lacking spine; third segment with 6 plumose setae. Endopod 3-segmented; first and second segment each with 1 plumose seta; third segment with 4 plumose setae and 1 distal spine. Outer margins of both rami partly or completely covered with rows of spinules.

Leg IV (Fig. 7D) coxa unarmed, basis with proximal outer seta. Exopod 2-segmented; first segment longest without armature; second segment with 5 plumose setae. Endopod 3-segmented; first and second segment each with 1 plumose seta; third segment with 3 plumose setae and 1 distal spine. Outer margins of both rami partly or completely covered with rows of spinules.

Leg V (Fig. 6H) reduced but visible, bearing 1 simple seta.

Specimens preserved in ethanol faint brown in colour, sometimes with dark brown spots in the cephalothorax.

Male: unknown.

Remarks

Ergasilus caparti n. sp. shows greatest similarity to E. cunningtoni (Capart, Reference Capart1944), a widely distributed copepod reported from fishes of many families, namely Alestidae, Cichlidae, Clupeidae, Cyprinidae, Distichodontidae, Mochokidae, Mormyridae (Campylomormyrus elephas – type host species) and Schilbeidae, from the Congo River System (Capart, Reference Capart1944; Fryer, Reference Fryer1964, Reference Fryer1967), the Galma River (Shotter, Reference Shotter1977) and Lake Volta (Paperna, Reference Paperna1969). In both species, the second endopodal segment of antenna has a conspicuous indentation of cuticle on outer side, formed by 2 ridges crossing each other. Ergasilus caparti n. sp. is differentiated from E. cunningtoni by: (i) having a much smaller body size (509 vs 970); (ii) having 2-segmented abdomen (vs 3-segmented abdomen in E. cunningtoni); (iii) the presence of a spine on the basis of legs III and IV; (iv) the absence of a spine on the first segment of the exopod of leg I; (v) the absence of seta on the first segment of endopod of leg I; (vi) the absence of a spine on the first segment of exopods of legs II and III; (vii) having only 1 seta on the second segments of the endopods of legs II, III and IV (vs 2 setae in E. cunningtoni); (viii) having a less prominent eyespot; (ix) the presence of spinules on the outer margins of both rami of all legs (vs both rami of all legs with smooth margins in E. cunningtoni).

Ergasilus parasarsi n. sp.

Type-host: S. diagramma (Günther, 1894)

Type-locality: Magara (3°44′S, 29°19′E), Lake Tanganyika, Burundi.

Other hosts and localities: E. marksmithi (locality 1), G. permaxillaris (locality 2), L. callipterus (locality 2), Ophthalmotilapia nasuta (locality 1), P. microlepis (locality 4), T. irsacae (locality 2) (see Table 1).

Type and voucher material: holotype (adult female): (Cr-36) ex S. diagramma; paratypes (adult females): Cr-36 ex T. irsacae; hologenophores (adult females): Cr-36 ex O. nasuta and T. irsacae.

Site on host: gill filaments.

Zoobank registration: urn:lsid:zoobank.org:act:E915E962-E162-4331-BB72-4CE17ADFE5E5

Representative DNA sequences: 18S rDNA (GenBank acc. no. OQ407467) and 28S rDNA (GenBank acc. no. OQ407473) (see also Table 2) sequences from 4 specimens ex L. callipterus (n = 2), O. nasuta (n = 1) and T. irsacae (n = 1).

Etymology: The specific name reflects the close morphological resemblance of the new species to E. sarsi (Capart, Reference Capart1944).

Description

Adult female [based on 10 specimens; Figs 8 and 9]. Body length (measured from anterior margin of prosome to posterior margin of caudal rami) 575 (455–694; n = 10). Body comprising prosome and urosome (Fig. 8A). Prosome 5-segmented, consisting of cephalosome and 4 pedigerous somites; cephalosome and first pedigerous somite separate.

Fig. 8. Ergasilus parasarsi n. sp., adult female from Simochromis diagramma. (A) Habitus, dorsal; (B) antenna, ventral; (C) mandible and maxilulle, ventral; (D) maxilla, ventral; (E) antennule, ventral; (F) abdomen and caudal rami; (G) egg sac, dorsal; (H) leg V, ventral.

Cephalosome slightly longer than wide, oval to trapezoidal, with antennules and antennae visible in dorsal view. Cephalic ornamentation comprising anterior circular marking and an inverted T-structure of thickened chitin situated medially on dorsal side. First pedigerous somite almost the same length as cephalosome; the other 3 pedigerous somites markedly shorter than the first one, decreasing in length and width posteriorly. Urosome comprising short fifth pedigerous somite, barrel-shaped genital segment (Fig. 8F) and 2 free abdominal somites. Genital segment with dorsal bilateral marking in the form of a stripe running lengthwise and a more laterally situated elongate spot, ventral surface ornate with spinules along postero-ventral margin. Two free abdominal somites with a row of acute spinules along posterior margin on ventral surface. First abdominal somite of similar length as the fifth pedigerous somite. Second abdominal somite deeply incised medially, much larger than the preceding somite. Caudal rami subrectangular, slightly wider than long; each ramus bearing 4 terminal setae – the innermost longest and thickest. Two cylindrical egg sacs (Fig. 8G) relatively short, not exceeding the longest furcal seta.

Antennule (Fig. 8E) 6-segmented, tapering distally, armed with simple setae; setal formula from proximal to distal segments: 0–8–3–1–2–6.

Antenna (Fig. 8B) prehensile, comprising short coxobasis, 3-segmented endopod and strongly curved terminal claw. First endopodal segment longest; second endopodal segment proximally with indentation of cuticle on outer side; third endopodal segment inconspicuous. Terminal claw about 1/4 length of second endopodal segment. Antenna without setules or spines.

Mouthparts (Fig. 8C and D) comprising mandible, maxillule and maxilla; maxilliped absent. Mandible consisting of 3 blades (anterior, middle and posterior); each blade with sharp teeth on anterior margin. Maxillule a single small lobe, bearing 2 almost equally long smooth setae. Maxilla 2-segmented; syncoxa unarmed; basis relatively slender, distally possessing numerous sharp teeth on anterior margin.

Swimming legs I to IV; each comprising coxa, basis and 2 segmented rami (i.e. exopod, endopod) (Fig. 9). Rami of all legs 3-segmented, except 2-segmented exopod of leg IV. Segments distinct, typical of members of the genus. Interpodal plates of all legs lacking spinules. Armature on rami as follows (Roman and Arabic numerals indicating spines and setae, respectively) in Table 7.

Fig. 9. Ergasilus parasarsi n. sp., adult female from Simochromis diagramma. (A) Leg I, ventral; (B) leg II, ventral; (C) leg III, ventral; (D) leg IV, ventral.

Table 7. Spine and setal formula of swimming legs of E. parasarsi n. sp.

Leg I (Fig. 9A) coxa and basis unarmed. Exopod 3-segmented; first segment with small outer spine; second segment with inner plumose seta, lacking spine; third segment with small spine on outer corner, longer apical spine and 5 plumose setae. Endopod 3-segmented; first segment and second segment each with 1 plumose seta, lacking spine; third segment with 4 plumose setae and 2 distal spines. Outer margins of both rami partly or completely covered with rows of spinules.

Legs II and III similar (Fig. 9B and C). Coxa and basis unarmed. Exopod 3-segmented; first segment lacking armature; second segment with 1 plumose seta, lacking spine; third segment with 6 plumose setae. Endopod 3-segmented; first and second segment each with 1 plumose seta; third segment with 4 plumose setae and 1 distal spine. Outer margins of both rami partly or completely covered with rows of spinules.

Leg IV (Fig. 9D) coxa and basis unarmed. Exopod 2-segmented; first segment longest without armature; second segment with 5 plumose setae. Endopod 3-segmented; first and second segment each with 1 plumose seta; third segment with 3 plumose setae and 1 distal spine. Outer margins of both rami partly or completely covered with rows of spinules.

Leg V (Fig. 8H) reduced but visible, bearing 2 simple setae located distally near each other.

Specimens preserved in ethanol rather light in colour. Traces of blue pigment in cephalothorax (i.e. cephalosome plus first pedigerous somite) observed after clearing in lactic acid.

Male: unknown.

Remarks

Ergasilus parasarsi n. sp. resembles E. sarsi that was described from the cichlid Tylochromis mylodon (Regan, 1920) from Lake Mweru, Congo Basin, DR Congo (Capart, Reference Capart1944; Fryer, Reference Fryer1968), and also reported from Lake Tanganyika without mentioning of host species (Sars, Reference Sars1909; Cunnington, Reference Cunnington1920; Capart, Reference Capart1944). It has also been found in Lake Bangwelu (Fryer, Reference Fryer1959), the Volta Basin (Paperna, Reference Paperna1969) and the River Galma in Niger (Shotter, Reference Shotter1977) from fishes of 5 families, namely Cichlidae, Clariidae, Mochokidae, Mormyridae and Poeciliidae. Detailed morphological comparison of our specimens with the type specimens of E. sarsi showed their non-conspecificity. Ergasilus parasarsi n. sp. differs from E. sarsi by the following characters: (i) different proportions of the first and second endopodal segments of the antenna (first segment much longer than second in E. sarsi); (ii) presence of a spine on the first segment of the exopod of leg I; (iii) the absence of a spine on the first segment of the exopod of leg IV; (iv) having only 1 seta on the second segment of the exopods of legs II, III and IV (vs 2 setae in E. sarsi); and (v) the presence of spinules on the outer margins of both rami of all legs (vs both rami of all legs with smooth margins in E. sarsi).

Ergasilus parvus n. sp.

Type-host: S. erythrodon (Boulenger, 1900)

Type-locality: Magara (3°44′S, 29°19′E), Lake Tanganyika, Burundi.

Other hosts and localities: B. ferox (fish market in Burundi), E. marksmithi (localities 1, 4), L. callipterus (locality 1), N. brichardi (locality 1), N. mondabu (locality 4) (see Table 1).

Type and voucher material: holotype (adult female): (Cr-37) ex S. erythrodon; paratype (adult female): (Cr-37) ex S. erythrodon; hologenophores (adult females): Cr-37 ex. S. erythrodon and L. callipterus.

Site on host: gill filaments.

Zoobank registration: urn:lsid:zoobank.org:act:40C5AD22-CF1E-4873-8F58-E0774928E368

Representative DNA sequences: 18S rDNA (GenBank acc. no. OQ407468) and 28S rDNA (GenBank acc. no. OQ407472) (see also Table 2) sequences from 6 specimens ex B. ferox (n = 1), E. marksmithi (n = 2), N. brichardi (n = 1) and S. erythrodon (n = 2).

Etymology: The specific name (an adjective) is from Latin (parvus = small) and refers to the body size.

Description

Adult female [based on 10 specimens; Figs 10 and 11]. Body length (measured from anterior margin of prosome to posterior margin of caudal rami) 475 (417–533; n = 10). Body comprising prosome and urosome (Fig. 10A). Prosome 5-segmented, composed of cephalosome and 4 pedigerous somites; cephalosome and first pedigerous somite separate. Cephalosome slightly wider than long, bluntly rounded anteriorly, bulged laterally, indented in posterior third, with antennules and antennae visible in dorsal view. Cephalic ornamentation comprising anterior circular marking and a more posterior, less visible oval marking; an inverted T-structure of thickened chitin situated medially on dorsal side, between the circular and oval marking. First 4 pedigerous somites well developed, decreasing in length and width posteriorly. Urosome comprising short fifth pedigerous somite, narrowed genital segment in posterior third (Fig. 10F) and 2 free abdominal somites decreasing in width posteriorly. Second abdominal somite incised medially, about as long as preceding somite. Caudal rami subrectangular, slightly longer than wide; each ramus armed with 3 terminal setae – the innermost longest and thickest. Two long egg sacs (Fig. 10G), much longer than wide, reaches past longest furcal seta; each composed of 2 rows of brick-shaped eggs.

Fig. 10. Ergasilus parvus n. sp., adult female from Spathodus erythrodon. (A) Habitus, dorsal; (B) antenna, ventral; (C) mandible and maxilulle, ventral; (D) maxilla, ventral; (E) antennule, ventral; (F) abdomen and caudal rami; (G) egg sac, dorsal; (H) leg V, ventral.

Antennule (Fig. 10E) 6-segmented, tapering distally, armed with simple setae; setal formula from proximal to distal segments: 3–8–4–4–2–4.

Antenna (Fig. 10B) prehensile, composed of short coxobasis, 3-segmented endopod and strongly curved terminal claw. First endopodal segment markedly more robust than the second one; second endopodal segment and terminal claw evenly curved ventrally; third endopodal segment inconspicuous. Terminal claw about 1/5 length of second endopodal segment. Antenna without setules, spines or indentations.

Mouthparts (Fig. 10C and D) comprising mandible, maxillule and maxilla; maxilliped absent. Mandible consisting of 3 blades (anterior, middle and posterior); each blade with sharp teeth on anterior margin. Maxilulle a single lobe, bearing 2 equally long setae. Maxilla 2-segmented, comprising unarmed syncoxa and basis; basis distally with numerous sharp teeth on anterior margin.

Swimming legs I–IV; each comprising coxa, basis and 2 segmented rami (i.e. exopod, endopod) (Fig. 11). Rami of all legs 3-segmented, except 2-segmented exopod of leg IV. Segments distinct, typical of members of the genus. Interpodal plates of all legs lacking spinules. Armature on rami as follows (Roman and Arabic numerals indicating spines and setae, respectively) in Table 8.

Fig. 11. Ergasilus parvus n. sp., adult female from Spathodus erythrodon. (A) Leg I, ventral; (B) leg II, ventral; (C) leg III, ventral; (D) leg IV, ventral.

Table 8. Spine and setal formula of swimming legs of E. parvus n. sp.

Leg I (Fig. 11A) with unarmed coxa and basis with outer seta. Exopod 3-segmented; first segment with small outer spine; second segment with inner plumose seta and small outer spine; third segment with small spine on outer corner, long apical spine and 5 plumose setae. Endopod 3-segmented; first and second segment each with plumose inner seta; third segment with small spine on outer corner, long apical spine and 4 plumose setae. Outer margins of both rami partly or completely covered with rows of spinules.

Legs II and III similar (Fig. 11B and C). Coxa unarmed, basis with outer seta. Exopod 3-segmented; first segment lacking armature; second segment with 1 plumose seta, lacking spine; third segment with 6 setae. Endopod 3-segmented; first and second segment each with 1 plumose seta; third segment with 4 plumose setae and 1 distal spine. Outer margins of both rami partly or completely covered with rows of spinules.

Leg IV (Fig. 11D) with unarmed coxa and basis having outer seta. Exopod 2-segmented; first segment longest with no armature; second segment with 5 plumose setae. Endopod 3-segmented; first segment lacking armature; second segment with 1 plumose seta; third segment with 3 plumose setae and distal spine. Outer margins of both rami partly or completely covered with rows of spinules.

Leg V (Fig. 10H) reduced but visible, bearing 2 simple seta located distally.

Specimens preserved in ethanol faint brown in colour; traces of a purple pigment in cephalosome sometimes observed after clearing in lactic acid.

Male: unknown.

Remarks

Based on the body shape and antenna morphology, E. parvus n. sp. is most similar to E. latus (Fryer, Reference Fryer1960), described from the mouthbrooding cichlid Oreochromis niloticus (Linnaeus, 1758) from Lake Turkana, Kenya (Fryer, Reference Fryer1960). Records of the latter species came also from Ghana (Thurston, Reference Thurston1970), the Niki River (Fryer, Reference Fryer1968), the River Galma (Shotter, Reference Shotter1977), Kitona (Fryer, Reference Fryer1963) and the Afram Basin, Mawli River and Peshi Lagoon (Paperna, Reference Paperna1969). Ergasilus parvus n. sp. is differentiated from E. latus by having: (i) a much smaller body size (475 vs 900); (ii) a small outer spine on the exopod of leg I; (iii) a seta on the second endopod segment of leg II; (iv) brick-shaped egg sacs (vs ovoid egg sacs in E. latus); (v) a less prominent leg V; and (vi) the presence of cephalic ornamentation (ovoid and circular marking) (vs only inverted T-structure present in E. latus).

Molecular characterization and phylogenetic position of Ergasilus species from Lake Tanganyika within the Ergasilidae

No intraspecific variability was detected for partial 18S and 28S rDNA sequences of Ergasilus species parasitizing cichlid fishes from Lake Tanganyika. The overall p-distance among Ergasilus species found for 18S and 28S rDNA sequences was 0.1 and 2% (see Table 9), respectively. Moreover, the 18S sequences displayed no or low (1 bp) interspecific variability; no differences were found among 18S rDNA sequences of E. macrodactylus, E. parvus n. sp. or E. caparti n. sp., or between sequences of E. megacheir or E. parasarsi n. sp. Ergasilus parasarsi n. sp. was revealed as the most genetically distant species to E. caparti n. sp. or E. megacheir (2.72%). The lowest values of interspecific differences (0.85%) were found between E. macrodactylus and E. parvus n. sp. or E. megacheir.

Table 9. Nucleotide comparison of the partial 28S rDNA sequences of family Ergasilidae based on 589 bp-long alignment

P-distance (%) is given below the diagonal and the number of variable nucleotides above the diagonal. Conditional formatting highlights the lowest p-distances in dark grey while higher values in light grey.

ML and BI analyses based on concatenated alignment including partial 18S and 28S rDNA sequences of Ergasilidae yielded trees with congruent topologies with similar nodal support values and revealed 4 well-supported groups (Fig. 12): (A) Ergasilus species from Lake Tanganyika cichlids, (B) Sinergasilus species and the E. anchoratus group, (C) Asian Ergasilus species and the Neoergasilus japonicus group and (D) Paraergasilus species and the E. wilsoni group. The present results are consistent with previously reported ergasilid phylogenies (Song et al., Reference Song, Wang, Yao, Gao and Nie2008; Santacruz et al., Reference Santacruz, Morales-Serna, Leal-Cardín, Barluenga and Pérez-Ponce de León2020; Kvach et al., Reference Kvach, Tkachenko, Seifertová and Ondračková2021) and suggest the polyphyletic status of the genus Ergasilus. Although Ergasilus species from Lake Tanganyika cichlids formed a well-supported clade, their position within Ergasilidae was not fully resolved due to the observed low support values as well as an insufficient amount of molecular data.

Fig. 12. Phylogenetic tree of Ergasilidae reconstructed by maximum likelihood. The tree is based on the combined sequences of partial genes coding 18S and 28S rRNA. Values along the branches indicate posterior probabilities from Bayesian inference and bootstrap values from maximum likelihood (dashes indicate values below 0.7 and 50, respectively). Letters (A)–(D) represent well-supported group of Ergasilidae.

Key for identification of Ergasilus species from Lake Tanganyika

  1. 1. (2) Five-segmented antennule3

  2. 2. (1) Six-segmented antennule5

  3. 3. (4) Second endopodal segment of antenna with outer denticle near its distal end; leg V 2-segmented, with 1 seta on reduced proximal segment and 2 setae on distal segment; caudal ramus with 1 long and 3 short setae.E. flaccidus

  4. 4. (3) Second endopodal segment of antenna with inner denticle near its proximal end; leg V reduced to 1 segment, with 4 setae; caudal ramus with 2 long and 2–3 short setaeE. kandti

  5. 5. (6) Each caudal ramus with 3 setae7

  6. 6. (5) Each caudal ramus with 4 setae9

  7. 7. (8) Second endopodal segment of antenna of similar diameter as first endopodal segment, with slight outer depression near its proximal end; cephalosome with smooth lateral margins, inverted T-structure having anteriorly recurved lateral ends (resembling a smile); gap between cephalosome and first thoracic segment clearly marked; leg V with 3 setae; 3-segmented abdomenE. sarsi

  8. 8. (7) Second endopodal segment of antenna much thinner than first endopodal segment, without depression; cephalosome bulged laterally, with inverted T-structure lacking anteriorly recurved lateral ends; leg V with 2 setae; 2-segmented abdomenE. parvus

  9. 9. (10) Second endopodal segment of antenna without depression; cephalosome trapezoidal, with inverted T-structure between circular and ovoid marking; leg V cylindrical, with 2 setae; 3-segmented abdomen; caudal ramus with 1 long and 3 short setaeE. macrodactylus

  10. 10. (9) Second endopodal segment of antenna with outer proximal depression11

  11. 11. (12) Terminal claw of antenna with small inner denticle; second endopodal segment of antenna short and twisted; anterior edge of first endopodal segment of antenna with thin hyaline border; cephalosome quadrangular, with inverted T-structure between circular and ovoid marking; leg V extremely small, with 1 seta; 2-segmented abdomenE. megacheir

  12. 12. (11) Terminal claw of antenna without a denticle13

  13. 13. (14) Second endopodal segment of antenna with conspicuous depression formed by 2 ridges crossing each other; cephalosome hexagonal, posterior margin with medial indentation, with inverted T-structure between circular and ovoid marking; first pedigerous somite slightly tapering medially, with inverted U marking; leg V with 1 setaE. caparti

  14. 14. (13) Second endopodal segment of antenna with indentation; cephalosome trapezoidal, with circular marking anterior to inverted T-structure; first pedigerous somite slightly tapering posteriorly; leg V with 2 setaeE. parasarsi

Discussion

Our investigation of crustacean parasites of cichlid fishes from Lake Tanganyika revealed the presence of 2 previously described and 3 new species of Ergasilus that were identified using a combined morphological and molecular approach. The occurrence of both previously described species (E. macrodactylus and E. megacheir) had already been confirmed in Lake Tanganyika in previous studies (Sars, Reference Sars1909; Cunnington, Reference Cunnington1920; Capart, Reference Capart1944; Fryer, Reference Fryer1965); host species for E. macrodactylus were not recorded (Sars, Reference Sars1909), and E. megacheir was found on 6 cichlids and 2 mochochid species of the genus Synodontis (Sars, Reference Sars1909; Cunnington, Reference Cunnington1920; Capart, Reference Capart1944; Fryer, Reference Fryer1965). The present study brings new host records for these species: E. marksmithi, G. permaxillaris, L. callipterus, P. microlepis and T. irsacae for E. macrodactylus and C. horei and S. diagramma for E. megacheir. The occurrence of both these species has also been recorded in other areas of Africa; E. megacheir was collected from the gills of 1 cichlid species, P. congicus (Boulenger, 1897), in Lake Tumba in the Lower Congo (Fryer, Reference Fryer1964) and the presence of E. macrodactylus was confirmed in Lake Malawi on 4 cichlid species and 1 alestid (Fryer, Reference Fryer1956). However, the first description of E. macrodactylus as well as its occurrence in Lake Tanganyika (Sars, Reference Sars1909) is doubtful, similarly to the description of E. brevimanus (Sars, Reference Sars1909). The present results confirmed the presence of E. macrodactylus in Lake Tanganyika for the first time since Sars (Reference Sars1909), even though the overall size of the body is smaller than Fryer's redescription (Fryer, Reference Fryer1956) from Lake Malawi. The main difference between both descriptions is the segmentation of the antennule (Sars mentions 5-segmented antennule, Fryer 6-segmented antennule). From this point of view, the material from Lake Tanganyika matches the Fryer's description, since the antennule is clearly 6-segmented.

Until now, there were no studies on the genetic characteristics of African Ergasilus species; thus, the molecular data presented here represent the first insight into the phylogenetic relationships of this genus in Africa. In contrast to data on the well-documented distribution of ergasilid copepods among host species and regions, molecular data for this large taxon remain scarce over the whole range of its global distribution. Among the 30 valid Ergasilidae genera, molecular data are currently only available for 7 [Acusicola (Cressey, 1970); Ergasilus; Gamispinus (Thatcher and Boeger, 1984); Miracetyma (Malta, 1993); Neoergasilus (Yin, 1956); Paraergasilus (Markevich, 1937); Sinergasilus (Yin, 1949) and Therodamas (Krøyer, 1863)]. Moreover, only molecular data belonging to species with an Asian origin were available for a long time (Song et al., Reference Song, Wang, Yao, Gao and Nie2008). Recently, molecular data for the cosmopolitan species E. sieboldi (von Nordmann, 1832) collected from European perch in the Czech Republic, and E. yandemontei (Waicheim, Mendes Marques, Rauque and Viozzi, 2021) from atherinid silversides in Argentina and for a few other genera of Ergasilidae have been published (Ondračková et al., Reference Ondračková, Fojtů, Seifertová, Kvach and Jurajda2019; Santacruz et al., Reference Santacruz, Morales-Serna, Leal-Cardín, Barluenga and Pérez-Ponce de León2020; Kvach et al., Reference Kvach, Tkachenko, Seifertová and Ondračková2021; Waicheim et al., Reference Waicheim, Mendes Marques, Rauque and Viozzi2021).

Based on the possibility to compare the genetic data of representatives of Ergasilidae, which are available in the GenBank database, molecular characterization of Ergasilus species in the present study was performed using 2 partial fragments of nuclear ribosomal DNA, i.e. 18S and 28S rDNA. Moreover, these 2 nuclear markers have been also applied in previous phylogenetic studies of Ergasilidae (Song et al., Reference Song, Wang, Yao, Gao and Nie2008; Santacruz et al., Reference Santacruz, Morales-Serna, Leal-Cardín, Barluenga and Pérez-Ponce de León2020; Kvach et al., Reference Kvach, Tkachenko, Seifertová and Ondračková2021). In the present study, no intraspecific genetic variability in both markers linked with host or locality was detected. However, low-intraspecific divergence in 18S and 28S rDNA was previously recorded in some representatives of ergasilid copepods (Song et al., Reference Song, Wang, Yao, Gao and Nie2008; Ondračková et al., Reference Ondračková, Fojtů, Seifertová, Kvach and Jurajda2019). The lake is 673 km-long, and only a relatively small part was sampled (the eastern shore of its northern end) and localities were roughly 100 km apart from each other. Therefore, a more extensive sampling comprising larger areas should be carried out to confirm genetic variability at the species level also in ergasilid species in Lake Tanganyika. Both genetic markers that were analysed differed in genetic distances (0.1% for 18S and 2% for 28S) among Ergasilus species in Lake Tanganyika. The 28S marker was shown to be much more efficient for species delimitation and the species found in this study were clearly resolved by means of its DNA sequence variability.

In contrast, the 18S marker was shown to be highly conservative within Ergasilus species found in Lake Tanganyika and almost no variability among species was observed. Previous phylogenetic studies confirmed that the 18S gene is more informative for resolving relationships between copepods at the genus and family levels (Huys et al., Reference Huys, Llewellyn-Hughes, Olson and Nagasawa2006; Marrone et al., Reference Marrone, Lo Brutto, Hundsdoerfer and Arculeo2013). Even though it is suitable for determining higher taxa, on the species level it does not show significant differences. This corresponds with previous studies which noted that 18S sequences are not suitable for determining the species-level richness of environmental samples, because they could underestimate species diversity (Tang et al., Reference Tang, Leasi, Obertegger, Kieneke, Barraclough and Fontaneto2012) and fail to resolve relationships between closely related species (Taniguchi et al., Reference Taniguchi, Kanehisa, Sawabe, Christen and Ikeda2004). Compared with the nuclear ribosomal genes, the commonly used barcoding gene, cytochrome c oxidase subunit I (COI mtDNA), has proven useful in free living copepods (Baek et al., Reference Baek, Jang, Choi, Ryu, Kim, Lee and Hwang2016; Mayor et al., Reference Mayor, Galimova, Sheveleva, Sukhanova and Kirilchik2017). Moreover, COI data display high resolution at species level and may be also more efficient for revealing intraspecific variation (Tang et al., Reference Tang, Leasi, Obertegger, Kieneke, Barraclough and Fontaneto2012). Since there are only 7 COI sequences from Ergasilus species [E. jaraquensis (Thatcher and Robertson B.A., 1982) (2 sequences), E. wilsoni (1 sequence) and Ergasilus sp. (4 sequences) published in the GenBank on 17 October 2022], the analysis of COI marker is more than suitable in future studies regarding this group of copepodes. Nevertheless, the use of Folmer's (Folmer et al., Reference Folmer, Hoeh, Black and Vrijenhoek1994) ‘universal’ COI primers has failed and showed to be problematic in the present study. Universal primers amplified non-ergasilid DNA pointing to contamination problems. Therefore, successful COI amplification in ergasilids will require above all the development of taxon-specific primers and to improve DNA barcoding protocols of parasitic copepods.

The phylogenetic reconstruction suggests that African ergasilids in Lake Tanganyika form a well-supported monophyletic lineage, though relationships within Ergasilidae still remain largely unresolved. This close relationship between Lake Tanganyika ergasilids may be related to the geographic origin of the species or to the endemism of their hosts. Assuming that parasite endemism correlates with the endemism of their hosts (Morand and Guégan, Reference Morand and Guégan2000) and assuming the existence of coevolution between parasites and their hosts, all newly described Ergasilus species could be considered as endemic to Lake Tanganyika. To date, at the level of parasitic crustaceans, 8 branchiuran species from the genus Argulus (Cunnington, Reference Cunnington1913; Fryer, Reference Fryer1965, Reference Fryer1968; Rushton-Mellor, Reference Rushton-Mellor1994a, Reference Rushton-Mellor1994b), 2 species of Lernaea (Cunnington, Reference Cunnington1914) and Ergasilus flaccidus (Fryer, Reference Fryer1965) collected from the endemic species Oreochromis tanganicae (Fryer, Reference Fryer1965) may also be considered as endemic species of Lake Tanganyika. The distributions of E. megachier and E. macrodactylus comprise other African areas (see below) and their host range includes also non-endemic host species. Molecular data would be particularly informative to support this hypothesis.

Overall, the relationships found within this family are consistent with previous phylogenetic analyses (Song et al., Reference Song, Wang, Yao, Gao and Nie2008; Santacruz et al., Reference Santacruz, Morales-Serna, Leal-Cardín, Barluenga and Pérez-Ponce de León2020; Kvach et al., Reference Kvach, Tkachenko, Seifertová and Ondračková2021; Oliveira et al., Reference Oliveira, Corrêa, Adriano and Tavares-Dias2021) and suggest that the genus Ergasilus is not monophyletic. Nevertheless, further morphological studies combined with molecular data are needed to elucidate the evolutionary relationships and origin of this diverse group of parasitic copepods.

Conclusion

The present study represents the first molecular and systematic update on ergasilids from Africa since more than 3 decades. The extent of the parasitic copepod fauna of the African region is most likely underestimated and harbours a great potential for discovering new species and new host records, using a similar approach combining morphological and molecular data. This study also highlights the need for further intensive genetic research on ergasilid species in order to elucidate the phylogenetic relationships within Ergasilidae. Future studies should consider using COI marker, since 18S rDNA is not suitable for species delimitation and 28S rDNA is limited.

Data availability

Type and voucher specimens were deposited in the Institute of Parasitology, Czech Academy of Sciences, České Budějovice, Czech Republic (accession codes Cr-33, Cr-34, Cr-35, Cr-36 and Cr-37). The sequences produced in this study were deposited in GenBank of NCBI at https://www.ncbi.nlm.nih.gov/ (accession codes OQ407465, OQ407466, OQ407467, OQ407468, OQ407469, OQ407470, OQ407471, OQ407472, OQ407473 and OQ407474).

Acknowledgements

The authors are grateful to M. P. Vanhove, Š. Mašová, V. Nezhybová and I. Přikrylová (Masaryk University, Czech Republic) for their help with fish dissection and parasite collection. The authors thank Professor G. Banyankimbona (University of Burundi), the Schreyen-Brichard family for their support during the fieldwork and R. Blažek (Czech Academy of Sciences) with S. Koblmüller (University of Graz, Austria) for fish identification. The authors also thank the technical staff of Fishes of Burundi, working in the ornamental fish sector, for acquiring the fishes for this study (since The Nagoya Protocol was not yet in action in 2014, no further permits for catching or export were needed at the time). Robert Míč specially thanks M. Dávidová for assisting in morphological identification of copepods. The authors also thank M. Lowe (Natural History Museum, London, UK) and Y. Samyn (Royal Belgium Institute of Natural Sciences, Belgium) for the kind loan of type specimens and comparative material. Besides, A. Šimková and M. Gelnar are thanked for guidance and help with funding the project. The authors are grateful to M. Nicholls for the English revision of the final version of the manuscript. The authors are also grateful to the 3 anonymous reviewers who provided helpful suggestions and feedback.

Author's contribution

R. M. and M. S. conceived and designed the study. E. Ř. collected parasitological material. R. M. performed morphological characterization and described the species. R. M. and M. S. performed molecular and phylogenetic analyses, and wrote the draft of the manuscript. E. Ř. reviewed descriptions of the species. All authors read and approved the final version of the manuscript.

Financial support

This study was financially supported by ECIP (European Centre of Ichthyoparasitology) – Centre of Excellence, Grant Agency of the Czech Republic, No. P505/12/G112. R. M. was supported by the Masaryk University, Czech Republic, project no. MUNI/A/1488/2021.

Conflict of interest

None.

Ethical standards

All applicable institutional, national and international guidelines for the care and use of animals were followed. This study was approved by the Animal Care and Use Committee of the Faculty of Science, Masaryk University in Brno (Czech Republic). This work is part of R. M.'s PhD study and it is a direct benefit to local fisheries biology as set within a broader ecosystem of current harvesting and an increasingly complex legislature.

References

Avenant-Oldewage, A and Oldewage, W (1993) Checklist of the parasitic Copepoda (Crustacea) of African fishes. Muséé Royal de l'Afrique Centrale Tervuren Belgique Documentation Zoologique 23, 128.Google Scholar
Baek, SY, Jang, KH, Choi, EH, Ryu, SH, Kim, SK, Lee, JH and Hwang, UW (2016) DNA barcoding of metazoan zooplankton copepods from South Korea. PLoS ONE 11, 120. doi: 10.1371/journal.pone.0157307CrossRefGoogle ScholarPubMed
Boxshall, GA and Defaye, D (2007) Global diversity of copepods (Crustacea: Copepoda) in freshwater. In Balian, EV, Lévêque, C, Segers, H and Martens, K (eds), Freshwater Animal Diversity Assessment. Dordrecht: Springer Netherlands, pp. 195207. doi: 10.1007/978-1-4020-8259-7_21Google Scholar
Boxshall, GA and Halsey, SH (2004) An Introduction to Copepod Diversity. London: Ray Society.Google Scholar
Boxshall, GA and Montú, MA (1997) Copepods parasitic on Brazilian coastal fishes: a handbook. Nauplius 5, 1225.Google Scholar
Bush, AO, Lafferty, KD, Lotz, JM and Shostak, AW (1997) Parasitology meets ecology on its own terms: Margolis, et al. revisited. The Journal of Parasitology 83, 575583.10.2307/3284227CrossRefGoogle Scholar
Capart, A (1944) Notes sur les Copépodes parasites. III. Copépodes parasites des poissons d'eau douce du Congo Belge. Bulletin du Musée Royal d'Histoire Naturelle de Belgique 20, 124.Google Scholar
Capart, A (1956) Quelques Copepodes parasites de poissons du Niger (Gourao) recoltes par Th. Monod. Bulletin de l'Institut français d'Afrique noire (A) 18, 485494.Google Scholar
Cohen, AS, Soreghan, MJ and Scholz, CA (1993) Estimating the age of formation of lakes: an example from Lake Tanganyika, East African Rift system. Geology 21, 511.10.1130/0091-7613(1993)021<0511:ETAOFO>2.3.CO;22.3.CO;2>CrossRefGoogle Scholar
Cunnington, WA (1913) Zoological results of the third Tanganika expedition, conducted by Dr. W.A. Cunnington, 1904-1905: report on the Branchiura. Proceedings of the Zoological Society of London 37, 252283.Google Scholar
Cunnington, WA (1914) 45. Zoological results of die third Tanganyika expedition, conducted by Dr. W. A. Cuunington, 1904–1905: report on the parasitic Encopepoda. Proceedings of the Zoological Society of London 84, 819829.10.1111/j.1469-7998.1914.tb07064.xCrossRefGoogle Scholar
Cunnington, WA (1920) 32. The fauna of the African lakes: a study in comparative limnology with special reference to Tanganyika. Proceedings of the Zoological Society of London 90, 507622.10.1111/j.1096-3642.1920.tb03243.xCrossRefGoogle Scholar
Darriba, D, Taboada, GL, Doallo, R and Posada, D (2012) jModelTest 2: more models, new heuristics and parallel computing. Nature Methods 9, 772772.10.1038/nmeth.2109CrossRefGoogle ScholarPubMed
Dávidová, M and Smit, N (2018) In: Scholz T, Vanhove MPM, Smit N, Jayasundera Z and Gelnar M (2018). A guide to the parasites of African freshwater fishes. Abc Taxa 18, 333355.Google Scholar
Fischer, C, Koblmüller, S, Börger, C, Michelitsch, G, Trajanoski, S, Schlötterer, C, Guelly, C, Thallinger, GG and Sturmbauer, C (2021) Genome sequences of Tropheus moorii and Petrochromis trewavasae, two eco-morphologically divergent cichlid fishes endemic to Lake Tanganyika. Scientific Reports 11, 4309.10.1038/s41598-021-81030-zCrossRefGoogle ScholarPubMed
Folmer, O, Hoeh, WR, Black, MB and Vrijenhoek, RC (1994) Conserved primers for PCR amplification of mitochondrial DNA from different invertebrate phyla. Molecular Marine Biology and Biotechnology 3, 294299.Google Scholar
Froese, R and Pauly, D (2022) FishBase. World Wide Web electronic publication, available from www.fishbase.org, 16 October 2022.Google Scholar
Fryer, G (1956) A report on the parasitic Copepoda and Branchiura of the fishes of Lake Nyasa. Proceedings of the Zoological Society of London 127, 293344.10.1111/j.1096-3642.1956.tb00473.xCrossRefGoogle Scholar
Fryer, G (1959) A report on the parasitic Copepoda and Branchiura of the fishes of Lake Bangweulu (Northern Rhodesia). Proceedings of the Zoological Society of London 132, 517550.10.1111/j.1469-7998.1959.tb05535.xCrossRefGoogle Scholar
Fryer, G (1960) Studies on some parasitic crustaceans on African freshwater fishes, with descriptions of a new copepod of the genus Ergasilus and a new branchiuran of the genus Chonopeltis. Proceedings of the Zoological Society of London 133, 629647.10.1111/j.1469-7998.1960.tb05584.xCrossRefGoogle Scholar
Fryer, G (1961) The parasitic Copepoda and Branchiura of the fishes of Lake Victoria and the Victoria Nile. Proceedings of the Zoological Society of London 137, 4160.10.1111/j.1469-7998.1961.tb06160.xCrossRefGoogle Scholar
Fryer, G (1963) Crusatacean parasites from cichlid fishes of the genus Tilapia in the Musée Royal de l'Afrique central. Revue de Zoologie et de Botanique Africaines 68, 386392.Google Scholar
Fryer, G (1964) Further studies on the parasitic Crustacea of African freshwater fishes. Proceedings of the Zoological Society of London 143, 79102.Google Scholar
Fryer, G (1965) Crustacean parasites of African freshwater fishes, mostly collected during the expeditions to Lake Tanganika, and to Lakes Kivu, Edward and 91 Albert by the Institut Royal des Sciences Naturelles de Belgique. Bulletin Institut Royal des Sciences Naturelles de Belgique 41, 122.Google Scholar
Fryer, G (1967) Parasitic copepods from African cichlids fishes in the Musée Royal de l'Afrique centrale. Revue de Zoologie et de Botanique Africaines 76, 357363.Google Scholar
Fryer, G (1968) The parasitic Crustacea of African freshwater fishes; their biology and distribution. Journal of Zoology 156, 4595.10.1111/j.1469-7998.1968.tb08578.xCrossRefGoogle Scholar
Gurney, R (1928) Some Copepoda from Tanganyika collected by Mr. S. R. B. Pask. Proceedings of the Zoological Society of London 98, 317332.10.1111/j.1469-7998.1928.tb07154.xCrossRefGoogle Scholar
Hayward, A, Tsuboi, M, Owusu, C, Kotrschal, A, Buechel, SD, Zidar, J, Cornwallis, CK, Løvlie, H and Kolm, N (2017) Evolutionary associations between host traits and parasite load: insights from Lake Tanganyika cichlids. Journal of Evolutionary Biology 30, 10561067.10.1111/jeb.13053CrossRefGoogle ScholarPubMed
Hoang, DT, Chernomor, O, von Haeseler, A, Minh, BQ and Vinh, LS (2018) UFBoot2: improving the ultrafast bootstrap approximation. Molecular Biology and Evolution 35, 518522.10.1093/molbev/msx281CrossRefGoogle ScholarPubMed
Huelsenbeck, JP and Ronquist, F (2001) MRBAYES: Bayesian inference of phylogenetic trees. Bioinformatics 17, 754755.10.1093/bioinformatics/17.8.754CrossRefGoogle ScholarPubMed
Huys, R and Boxshall, GA (1991) Copepod Evolution. London: Ray Society (Publications).Google Scholar
Huys, R, Llewellyn-Hughes, J, Olson, PD and Nagasawa, K (2006) Small subunit rDNA and Bayesian inference reveal Pectenophilus ornatus (Copepoda incertae sedis) as highly transformed Mytilicolidae, and support assignment of Chondracanthidae and Xarifiidae to Lichomolgoidea (Cyclopoida). Biological Journal of the Linnean Society 87, 403425.10.1111/j.1095-8312.2005.00579.xCrossRefGoogle Scholar
Irisarri, I, Singh, P, Koblmüller, S, Torres-Dowdall, J, Henning, F, Franchini, P, Fischer, C, Lemmon, AR, Lemmon, EM, Thallinger, GG, Sturmbauer, C and Meyer, A (2018) Phylogenomics uncovers early hybridization and adaptive loci shaping the radiation of Lake Tanganyika cichlid fishes. Nature Communications 9, 3159.10.1038/s41467-018-05479-9CrossRefGoogle ScholarPubMed
Ivory, SJ, McGlue, MM, Peterman, C, Baldwin, P, Lucas, J, Cohen, A, Russell, J, Saroni, J, Msaky, E, Kimirei, I and Soreghan, M (2021) Climate, vegetation, and weathering across space and time in Lake Tanganyika (tropical eastern Africa). Quaternary Science Advances 3, 100023.10.1016/j.qsa.2021.100023CrossRefGoogle Scholar
Katoh, K and Standley, DM (2013) MAFFT multiple sequence alignment software version 7: improvements in performance and usability. Molecular Biology and Evolution 30, 772780.10.1093/molbev/mst010CrossRefGoogle ScholarPubMed
Kilian, E and Avenant-Oldewage, A (2013) Infestation and pathological alterations by Ergasilus sarsi (Copepoda) on the Tanganyika Killifish from Africa. Journal of Aquatic Animal Health 25, 237242.10.1080/08997659.2013.812874CrossRefGoogle ScholarPubMed
Kmentová, N, van Steenberge, M, Raeymaekers, JAM, Koblmüller, S, Hablützel, PI, Bukinga, FM, N'sibula, TM, Mulungula, PM, Nzigidahera, B, Ntakimazi, G, Gelnar, M and Vanhove, MPM (2018) Monogenean parasites of sardines in Lake Tanganyika: diversity, origin and intraspecific variability. Contributions to Zoology 87, 105132.10.1163/18759866-08702004CrossRefGoogle Scholar
Koblmüller, S, Zangl, L, Börger, C, Daill, D, Vanhove, MPM, Sturmbauer, C and Sefc, KM (2019) Only true pelagics mix: comparative phylogeography of deepwater bathybatine cichlids from Lake Tanganyika. Hydrobiologia 832, 93103.10.1007/s10750-018-3752-3CrossRefGoogle ScholarPubMed
Kondo, T and Hori, M (1986) Abundance of zooplankters on a rocky shore of Lake Tanganyika: a preliminary report. African Study Monographs 6, 1723.Google Scholar
Kvach, Y, Tkachenko, MY, Seifertová, M and Ondračková, M (2021) Insights into the diversity, distribution and phylogeny of three ergasilid copepods (Hexanauplia: Ergasilidae) in lentic water bodies of the Morava river basin, Czech Republic. Limnologica 91, 125922.10.1016/j.limno.2021.125922CrossRefGoogle Scholar
Marques, TM, Boeger, WA and de Carvalho Brasil-Sato, M (2015) Two new species of Ergasilus Nordmann, 1832 (Copepoda: Ergasilidae) and a redescription of Ergasilus salmini Thatcher & Brazil-Sato, 2008 from Salminus brasiliensis Cuvier and S. franciscanus Lima & Britsky (Teleostei: Characidae) in Brazil. Systematic Parasitology 90, 8189.10.1007/s11230-014-9529-9CrossRefGoogle Scholar
Marrone, F, Lo Brutto, S, Hundsdoerfer, AK and Arculeo, M (2013) Overlooked cryptic endemism in copepods: systematics and natural history of the calanoid subgenus Occidodiaptomus Borutzky 1991 (Copepoda, Calanoida. Diaptomidae). Molecular Phylogenetics and Evolution 66, 190202.10.1016/j.ympev.2012.09.016CrossRefGoogle ScholarPubMed
Mayor, TY, Galimova, YA, Sheveleva, NG, Sukhanova, LV and Kirilchik, SV (2017) Molecular phylogenetic analysis of Diacyclops and Acanthocyclops (Copepoda: Cyclopoida) from Lake Baikal based on COI gene. Russian Journal of Genetics 53, 252258.10.1134/S1022795417020041CrossRefGoogle Scholar
Miller, MA, Pfeiffer, W and Schwartz, T (2010) Creating the CIPRES Science Gateway for inference of large phylogenetic trees. In 2010 Gateway Computing Environments Workshop (GCE), pp. 1–8. IEEE. doi: 10.1109/GCE.2010.5676129CrossRefGoogle Scholar
Morand, S and Guégan, J-F (2000) Patterns of endemism in host-parasite associations: lessons from epidemiological models and comparative tests. Belgian Journal of Entomology 2, 135147.Google Scholar
Muriel-Hoyos, F, Santana-Piñeros, AM, Cruz-Quintana, Y and Suárez-Morales, E (2015) A new species of Ergasilus Nordmann, 1832 (Copepoda: Cyclopoida: Ergasilidae) from Bryconops giacopinii Fernández-Yépez (Characidae) in the Vichada River Basin, Colombia. Systematic Parasitology 92, 241249.10.1007/s11230-015-9599-3CrossRefGoogle ScholarPubMed
Narciso, RB, Brandão, H, Perbiche-Neves, G and da Silva, RJ (2020) A new species of Rhinergasilus Boeger et Thatcher, 1988 (Copepoda: Ergasilidae) from gills of Astyanax fasciatus (Cuvier, 1819) (Actinopterygii: Characidae). Acta Parasitologica 65, 327334.10.2478/s11686-020-00168-4CrossRefGoogle ScholarPubMed
Nguyen, L-T, Schmidt, HA, von Haeseler, A and Minh, BQ (2015) IQ-TREE: a fast and effective stochastic algorithm for estimating maximum-likelihood phylogenies. Molecular Biology and Evolution 32, 268274.10.1093/molbev/msu300CrossRefGoogle ScholarPubMed
Oldewage, WH and van As, JG (1988) A key for the identification of African piscine parasitic Ergasilidae (Copepoda:Poecilostomatoida). South African Journal of Zoology 23, 4246.10.1080/02541858.1988.11448075CrossRefGoogle Scholar
Oliveira, MSB, Corrêa, LL, Adriano, EA and Tavares-Dias, M (2021) Integrative taxonomy of a new species of Therodamas (Ergasilidae) infecting the Amazonian freshwater fish Leporinus fasciatus (Anostomidae). Parasitology Research 120, 31373147.10.1007/s00436-021-07256-yCrossRefGoogle ScholarPubMed
Ondračková, M, Fojtů, J, Seifertová, M, Kvach, Y and Jurajda, P (2019) Non-native parasitic copepod Neoergasilus japonicus (Harada, 1930) utilizes non-native fish host Lepomis gibbosus (L.) in the floodplain of the River Dyje (Danube basin). Parasitology Research 118, 5762.10.1007/s00436-018-6114-1CrossRefGoogle ScholarPubMed
Paperna, ILAN (1969) Parasitic Crustacea from fishes of the Volta basin and South Ghana. Revue de Zoologie et de Botanique Africaines 80, 208216.Google Scholar
Pleijel, F, Jondelius, U, Norlinder, E, Nygren, A, Oxelman, B, Schander, C, Sundberg, P and Thollesson, M (2008) Phylogenies without roots? A plea for the use of vouchers in molecular phylogenetic studies. Molecular Phylogenetics and Evolution 48, 369371.10.1016/j.ympev.2008.03.024CrossRefGoogle Scholar
Raeymaekers, JA, Hablützel, PI, Grégoir, AF, Bamps, J, Roose, AK, Vanhove, MP, van Steenberge, M, Pariselle, A, Huyse, T, Snoeks, J and Volckaert, FA (2013) Contrasting parasite communities among allopatric colour morphs of the Lake Tanganyika cichlid Tropheus. BMC Evolutionary Biology 13, 41.10.1186/1471-2148-13-41CrossRefGoogle ScholarPubMed
Raffini, F, Fruciano, C and Meyer, A (2018) Morphological and genetic correlates in the left–right asymmetric scale-eating cichlid fish of Lake Tanganyika. Biological Journal of the Linnean Society 124, 6784.10.1093/biolinnean/bly024CrossRefGoogle Scholar
Rahmouni, C, Vanhove, MPM and Šimková, A (2017) Underexplored diversity of gill monogeneans in cichlids from Lake Tanganyika: eight new species of Cichlidogyrus Paperna, 1960 (Monogenea: Dactylogyridae) from the northern basin of the lake, with remarks on the vagina and the heel of the male copulatory organ. Parasites & Vectors 10, 591.10.1186/s13071-017-2460-6CrossRefGoogle ScholarPubMed
Rahmouni, C, Vanhove, MPM and Šimková, A (2018) Seven new species of Cichlidogyrus Paperna, 1960 (Monogenea: Dactylogyridae) parasitizing the gills of Congolese cichlids from northern Lake Tanganyika. PeerJ 6, e5604.10.7717/peerj.5604CrossRefGoogle ScholarPubMed
Rambaut, A (2012) FigTree v1.4.3 [Computer software]. Available from https://github.com/rambaut/figtree/releases, 15 April 2022.Google Scholar
Rambaut, A, Drummond, AJ, Xie, D, Baele, G and Suchard, MA (2018) Posterior summarization in Bayesian phylogenetics using Tracer 1.7. Systematic Biology 67, 901904.10.1093/sysbio/syy032CrossRefGoogle ScholarPubMed
Ronco, F, Matschiner, M, Böhne, A, Boila, A, Büscher, HH, el Taher, A, Indermaur, A, Malinsky, M, Ricci, V, Kahmen, A, Jentoft, S and Salzburger, W (2021) Drivers and dynamics of a massive adaptive radiation in cichlid fishes. Nature 589, 7681.10.1038/s41586-020-2930-4CrossRefGoogle ScholarPubMed
Rushton-Mellor, SK (1994a) The genus Argulus (Crustacea: Branchiura) in Africa: two new species, A. fryeri and A. gracilis, the previously undescribed male of A. brachypeltis Fryer and the identity of the male described as A. ambloplites Wilson. Systematic Parasitology 28, 2331.10.1007/BF00006907CrossRefGoogle Scholar
Rushton-Mellor, SK (1994b) The genus Argulus (Crustacea: Branchiura) in Africa: redescriptions of type-material collected by W.A. Cunnington during the Lake Tanganyika Expedition in 1913, with notes on A. giganteus Lucas and A. arcassonensis Cuénot. Systematic Parasitology 28, 3349.10.1007/BF00006908CrossRefGoogle Scholar
Ryan, EK, Soreghan, MJ, McGlue, MM, Todd, JA, Michel, E, Kaufman, DS and Kimirei, I (2020) Paleoenviromental implications of time-averaging and taphonomic variation of shell beds in Lake Tanganyika, Africa. PALAIOS 35, 4966.10.2110/palo.2019.037CrossRefGoogle Scholar
Santacruz, A, Morales-Serna, FN, Leal-Cardín, M, Barluenga, M and Pérez-Ponce de León, G (2020) Acusicola margulisae n. sp. (Copepoda: Ergasilidae) from freshwater fishes in a Nicaraguan crater lake based on morphological and molecular evidence. Systematic Parasitology 97, 165177.10.1007/s11230-020-09906-8CrossRefGoogle Scholar
Sars, GOP (1909) Zoological results of the third Tanganyika expedition, conducted by Dr. W. A. Cunnington, F.Z.S., 1904–1905: report on the Copepoda. Proceedings of the Zoological Society of London 79, 3177.10.1111/j.1096-3642.1909.tb01855.xCrossRefGoogle Scholar
Satoh, S, Ota, K, Awata, S and Kohda, M (2019) Dynamics of sibling aggression of a cichlid fish in Lake Tanganyika. Hydrobiologia 832, 201213.10.1007/s10750-018-3768-8CrossRefGoogle Scholar
Satoh, S, Saeki, T, Kohda, M and Awata, S (2022) Cooperative breeding in Neolamprologus bifasciatus, a cichlid fish inhabiting the deep reefs of Lake Tanganyika. Ecology of Freshwater Fish 31, 640649. doi: 10.1111/eff.12658CrossRefGoogle Scholar
Scholz, T, Vanhove, MPM, Smit, N, Jayasundera, Z and Gelnar, M (2018) A Guide to the Parasites of African Freshwater Fishes. Brussels: Royal Belgian Institute of Natural Sciences, p. 424.Google Scholar
Shotter, RA (1977) Copepod parasites of fishes from northern Nigeria. Bulletin de l'Institut fondamental d'Afrique noire 39, 583600.Google Scholar
Smit, N and Hadfield, K (2018) In: Scholz T, Vanhove MPM, Smit N, Jayasundera Z and Gelnar M (2018). A guide to the parasites of African freshwater fishes. Abc Taxa 18, 333355.Google Scholar
Snoeks, J (2000) How well known is the ichthyodiversity of the large East African lakes?. Advances in Ecological Research 31, 1738. doi: 10.1016/S0065-2504(00)31005-4CrossRefGoogle Scholar
Song, Y, Wang, GT, Yao, WJ, Gao, Q and Nie, P (2008) Phylogeny of freshwater parasitic copepods in the Ergasilidae (Copepoda: Poecilostomatoida) based on 18S and 28S rDNA sequences. Parasitology Research 102, 299306.10.1007/s00436-007-0764-8CrossRefGoogle ScholarPubMed
Suárez-Morales, E and Santana-Piñeros, AM (2008) A new species of Ergasilus (Copepoda:Cyclopoida:Ergasilidae) from coastal fishes of the Mexican Pacific. Folia Parasitologica 55, 224230.10.14411/fp.2008.030CrossRefGoogle ScholarPubMed
Taborda, NL, Paschoal, F and Luque, JL (2016) A new species of Ergasilus (Copepoda: Ergasilidae) from Geophagus altifrons and G. argyrostictus (Perciformes: Cichlidae) in the Brazilian Amazon. Acta Parasitologica 61, 549555. doi: 10.1515/ap-2016-0073CrossRefGoogle Scholar
Takahashi, T (2003) Systematics of Tanganyikan cichlid fishes (Teleostei: Perciformes). Ichthyological Research 50, 367382.10.1007/s10228-003-0181-7CrossRefGoogle Scholar
Takahashi, T and Koblmüller, S (2011) The adaptive radiation of cichlid fish in Lake Tanganyika: a morphological perspective. International Journal of Evolutionary Biology 2011, 114.10.4061/2011/620754CrossRefGoogle ScholarPubMed
Talavera, G and Castresana, J (2007) Improvement of phylogenies after removing divergent and ambiguously aligned blocks from protein sequence alignments. Systematic Biology 56, 564577.10.1080/10635150701472164CrossRefGoogle ScholarPubMed
Tamura, K, Stecher, G and Kumar, S (2021) MEGA11: molecular evolutionary genetics analysis version 11. Molecular Biology and Evolution 38, 30223027.10.1093/molbev/msab120CrossRefGoogle ScholarPubMed
Tang, CQ, Leasi, F, Obertegger, U, Kieneke, A, Barraclough, TG and Fontaneto, D (2012) The widely used small subunit 18S rDNA molecule greatly underestimates true diversity in biodiversity surveys of the meiofauna. Proceedings of the National Academy of Sciences 109, 1620816212.10.1073/pnas.1209160109CrossRefGoogle ScholarPubMed
Taniguchi, M, Kanehisa, T, Sawabe, T, Christen, R and Ikeda, T (2004) Molecular phylogeny of Neocalanus copepods in the subarctic Pacific Ocean, with notes on non-geographical genetic variations for Neocalanus cristatus. Journal of Plankton Research 26, 12491255.10.1093/plankt/fbh115CrossRefGoogle Scholar
Thurston, JP (1970) The incidence of Monogenea and parasitic Crustacea on the gills of fish in Uganda. Revue de Zoologie et de Botanique Africaines 82, 111130.Google Scholar
Trifinopoulos, J, Nguyen, L-T, von Haeseler, A and Minh, BQ (2016) W-IQ-TREE: a fast online phylogenetic tool for maximum likelihood analysis. Nucleic Acids Research 44, W232W235.10.1093/nar/gkw256CrossRefGoogle ScholarPubMed
van Douwe, C (1912) Copepoda. Neue Süsswasser-Copepoden aus Südafrica. Zoolog, und Anthropol. Ergebnisse einer Forschungreise im westlichen u. zen tralen Südafrica in den Jahre 1908–1905 von Dr. Leonard Schultze. Systematik und Tiergeographie Lief 1, 2332.Google Scholar
Vanhove, MPM, Pariselle, A, van Steenberge, M, Raeymaekers, JAM, Hablützel, PI, Gillardin, C, Hellemans, B, Breman, FC, Koblmüller, S, Sturmbauer, C, Snoeks, J, Volckaert, FAM and Huyse, T (2015) Hidden biodiversity in an ancient lake: phylogenetic congruence between Lake Tanganyika tropheine cichlids and their monogenean flatworm parasites. Scientific Reports 5, 13669.10.1038/srep13669CrossRefGoogle Scholar
Varella, AMB, Morey, GAM and de Oliveira Malta, JC (2019) Ergasilus tipurus n. sp. (Copepoda: Ergasilidae), a parasite of Brazilian Amazon fish species. Acta Parasitologica 64, 187194.10.2478/s11686-018-00020-wCrossRefGoogle Scholar
Waicheim, MA, Mendes Marques, T, Rauque, CA and Viozzi, G (2021) New species of Ergasilus von Nordmann, 1832 (Copepoda: Ergasilidae) from the gills of freshwater fishes in Patagonia, Argentina. Systematic Parasitology 98, 131139.10.1007/s11230-021-09966-4CrossRefGoogle ScholarPubMed
Wilson, CB (1924) Parasitic copepods from the White Nile and the Red Sea. In Jägerskiöld, ALKE (ed.), Results of the Swedish Zoological Expedition to Egypt and the White Nile, Vol. 5, 3 Uppsala: Royal University of Uppsala, pp. 117.Google Scholar
WoRMS Editorial Board (2022) World register of marine species. Available from https://www.marinespecies.org/ at VLIZ, 16 October 2022.Google Scholar
Figure 0

Fig. 1. Map of Lake Tanganyika indicating the sampling localities along the northeastern shore in Burundi: (1) Magara; (2) Mukuruka; (3) Mvugo; (4) Nyaruhongoka.

Figure 1

Table 1. List of all sampled fishes and their sampling localities

Figure 2

Table 2. List of parasitic copepods used for phylogenetic analysis, including their host species, collection locality and accession numbers for partial 18S and 28S rDNA sequences

Figure 3

Table 3. Prevalence (first line), mean intensity of infection (second line) and intensity of infection (min–max; third line) of 5 Ergasilus species from Lake Tanganyika found on 12 cichlid host species (n = total number of host specimens examined)

Figure 4

Fig. 2. Ergasilus macrodactylus, adult female from Gnathochromis permaxillaris. (A) Habitus, dorsal; (B) antenna, ventral; (C) mandible and maxilulle, ventral; (D) maxilla, ventral; (E) antennule, ventral; (F) abdomen and caudal rami; (G) egg sac, dorsal; (H) leg V, ventral.

Figure 5

Fig. 3. Ergasilus macrodactylus, adult female from Gnathochromis permaxillaris. (A) Leg I, ventral; (B) leg II, ventral; (C) leg III, ventral; (D) leg IV, ventral.

Figure 6

Table 4. Spine and setal formula of swimming legs of E. macrodactylus

Figure 7

Fig. 4. Ergasilus megacheir, adult female from Simochromis diagramma. (A) Habitus, dorsal; (B) antenna, ventral; (C) mandible and maxilulle, ventral; (D) maxilla, ventral; (E) antennule, ventral; (F) abdomen and caudal rami; (G) egg sac, dorsal; (H) leg V, ventral.

Figure 8

Fig. 5. Ergasilus megacheir, adult female from Simochromis diagramma. (A) Leg I, ventral; (B) leg II, ventral; (C) leg III, ventral; (D) leg IV, ventral.

Figure 9

Table 5. Spine and setal formula of swimming legs of E. megacheir

Figure 10

Fig. 6. Ergasilus caparti n. sp., adult female from Neolamprologus brichardi. (A) Habitus, dorsal; (B) antenna, ventral; (C) mandible and maxilulle, ventral; (D) maxilla, ventral; (E) antennule, ventral; (F) abdomen and caudal rami; (G) egg sac, dorsal; (H) leg V, ventral.

Figure 11

Fig. 7. Ergasilus caparti n. sp., adult female from Neolamprologus brichardi. (A) Leg I, ventral; (B) leg II, ventral; (C) leg III, ventral; (D) leg IV, ventral.

Figure 12

Table 6. Spine and setal formula of swimming legs of E. caparti n. sp.

Figure 13

Fig. 8. Ergasilus parasarsi n. sp., adult female from Simochromis diagramma. (A) Habitus, dorsal; (B) antenna, ventral; (C) mandible and maxilulle, ventral; (D) maxilla, ventral; (E) antennule, ventral; (F) abdomen and caudal rami; (G) egg sac, dorsal; (H) leg V, ventral.

Figure 14

Fig. 9. Ergasilus parasarsi n. sp., adult female from Simochromis diagramma. (A) Leg I, ventral; (B) leg II, ventral; (C) leg III, ventral; (D) leg IV, ventral.

Figure 15

Table 7. Spine and setal formula of swimming legs of E. parasarsi n. sp.

Figure 16

Fig. 10. Ergasilus parvus n. sp., adult female from Spathodus erythrodon. (A) Habitus, dorsal; (B) antenna, ventral; (C) mandible and maxilulle, ventral; (D) maxilla, ventral; (E) antennule, ventral; (F) abdomen and caudal rami; (G) egg sac, dorsal; (H) leg V, ventral.

Figure 17

Fig. 11. Ergasilus parvus n. sp., adult female from Spathodus erythrodon. (A) Leg I, ventral; (B) leg II, ventral; (C) leg III, ventral; (D) leg IV, ventral.

Figure 18

Table 8. Spine and setal formula of swimming legs of E. parvus n. sp.

Figure 19

Table 9. Nucleotide comparison of the partial 28S rDNA sequences of family Ergasilidae based on 589 bp-long alignment

Figure 20

Fig. 12. Phylogenetic tree of Ergasilidae reconstructed by maximum likelihood. The tree is based on the combined sequences of partial genes coding 18S and 28S rRNA. Values along the branches indicate posterior probabilities from Bayesian inference and bootstrap values from maximum likelihood (dashes indicate values below 0.7 and 50, respectively). Letters (A)–(D) represent well-supported group of Ergasilidae.