Hostname: page-component-cd9895bd7-7cvxr Total loading time: 0 Render date: 2024-12-26T01:08:29.044Z Has data issue: false hasContentIssue false

The myxozoan parasite Myxobolus bejeranoi (Cnidaria: Myxozoa) infection dynamics and host specificity in hybrid tilapia aquaculture

Published online by Cambridge University Press:  10 March 2023

Keren Maor-Landaw
Affiliation:
Marine Biology Department, The Leon H. Charney School of Marine Sciences, University of Haifa, Mt. Carmel, 3498838 Haifa, Israel
Itamar Avidor
Affiliation:
Marine Biology Department, The Leon H. Charney School of Marine Sciences, University of Haifa, Mt. Carmel, 3498838 Haifa, Israel
Barbara Salti
Affiliation:
Marine Biology Department, The Leon H. Charney School of Marine Sciences, University of Haifa, Mt. Carmel, 3498838 Haifa, Israel
Margarita Smirnov
Affiliation:
Department of Fisheries and Aquaculture, Central Fish Health Laboratory, Ministry of Agriculture and Rural Development, 10803 Nir David, Israel
Vera Brekhman
Affiliation:
Marine Biology Department, The Leon H. Charney School of Marine Sciences, University of Haifa, Mt. Carmel, 3498838 Haifa, Israel
Tamar Lotan*
Affiliation:
Marine Biology Department, The Leon H. Charney School of Marine Sciences, University of Haifa, Mt. Carmel, 3498838 Haifa, Israel
*
Author for correspondence: Tamar Lotan, E-mail: [email protected]

Abstract

Nile × blue tilapia hybrid (Oreochromis niloticus × O. aureus) has become an important food fish in intensive freshwater aquaculture. Recently, the parasite Myxobolus bejeranoi (Cnidaria: Myxozoa) was found to infect hybrid tilapia gills at high prevalence, causing immune suppression and high mortality. Here, we explored additional characteristics of M. bejeranoi–tilapia interaction, which enable efficient proliferation of this parasite inside its specific host. Highly sensitive quantitative polymerase chain reaction (qPCR) and in situ hybridization analyses of fry collected from fertilization ponds provided evidence to an early-life infection of fish by a myxozoan parasite, occurring less than 3 weeks post-fertilization. Because Myxobolus species are highly host-specific, we next compared infection rates in hybrid tilapia and in both its parental species following a 1-week exposure to infectious pond water. Analysis by qPCR and histological sections showed that while blue tilapia was as susceptible to M. bejeranoi as the hybrid, Nile tilapia appeared to be resistant. This is the first report of differential susceptibility of a hybrid fish vs its parental purebreds to a myxozoan parasite. These findings advance our understanding of the relationship between M. bejeranoi and tilapia fish and raise important questions regarding the mechanisms that allow the parasite to distinguish between very closely related species and to infect a specific organ at very early-life stages.

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

Tilapia (family Cichlidae) is the second most cultured fish worldwide (El-Sayed, Reference El-Sayed and El-Sayed2020), and in Israel, it constitutes 60% of the total freshwater fish production (Hulata, Reference Hulata2014). Intensive aquaculture systems of earthen ponds containing an all-male hybrid of Oreochromis niloticus (Nile tilapia) females × O. aureus (Jordan/blue tilapia) males (Milstein et al., Reference Milstein, Zoran, Kochba and Avnimelech2001; Eknath and Hulata, Reference Eknath and Hulata2009; El-Sayed, Reference El-Sayed and El-Sayed2020) have become a common practice all over the world and also in Israel (Milstein et al., Reference Milstein, Zoran, Kochba and Avnimelech2001; Miao and Wang, Reference Miao and Wang2020). This is because of the fast growth, tolerance to a wide range of environmental conditions and resistance to stress of the hybrid, as well as the ability of the parents to reproduce effectively in captivity (El-Sayed, Reference El-Sayed and El-Sayed2020; Xiao et al., Reference Xiao, Chen, Wang, Zou, Wang, Li, Zhu, Yu and Yang2022). However, in the last 15 years, intense infections with a myxozoan parasite have been reported in Israeli fishponds.

Myxozoa is a large group of microscopic obligate endoparasites that has recently been placed within the phylum Cnidaria, alongside corals, sea anemones, jellyfish and hydroids [recently reviewed by Atkinson et al. (Reference Atkinson, Bartholomew and Lotan2018)]. They have complex life cycles, infecting both vertebrates (mostly fish) and invertebrates (mostly annelid worms) in freshwater and marine environments (Eszterbauer et al., Reference Eszterbauer, Atkinson, Diamant, Morris, El-Matbouli, Hartikainen, Okamura, Gruhl and Bartholomew2015; Holzer et al., Reference Holzer, Barto, Born-torrijos, Alena, Hartigan and Fiala2018). Transmission between hosts is achieved by 2 distinct types of waterborne spores: myxospores that develop in fish and when released infect the worm host, and actinospores that develop in worm and infect fish (Wolf and Markiw, Reference Wolf and Markiw1984; Kent et al., Reference Kent, Margolis and Corliss1994). An infected worm can propagate thousands of actinospores to the water column (Gilbert and Granath, Reference Gilbert and Granath2001). Myxozoan parasites cause morbidity and mortality, such as whirling disease and proliferative kidney disease, in both farmed and wild fish populations worldwide (Okamura et al., Reference Schmidt-Posthaus, Wahli, Okamura and Gruhl2015). Recently, the causative agent of hybrid tilapia infections, which occur at more than 50% prevalence during the summer season in commercial fish ponds (Maor-Landaw et al., Reference Maor-Landaw, Smirnov, Brekhman, Ofek-lalzar, Yahav and Lotan2022), was classified as Myxobolus bejeranoi (Lövy et al., Reference Lövy, Smirnov, Brekhman, Ofek and Lotan2018). The infection is limited to the gills, where cysts are formed on striated muscle of the gill filament base (Lövy et al., Reference Lövy, Smirnov, Brekhman, Ofek and Lotan2018). Nevertheless, we showed recently that the effects are systemic, as inhibition of the haematopoietic organs such as head, kidney and spleen results in immune suppression and high mortality (Maor-Landaw et al., Reference Maor-Landaw, Smirnov, Brekhman, Ofek-lalzar, Yahav and Lotan2022). Thus, M. bejeranoi infection of hybrid tilapia has high economic impact on commercial fish farms.

As all Oreochromis species, hybrid tilapia reproduce by maternal mouthbrooding. Females repeatedly release strings of 20–50 eggs to the bottom, which are then fertilized by the male as it passes over them. Immediately afterwards, the female returns and picks the fertilized eggs into its buccal cavity. Fertilized eggs will be incubated for 3–6 days in the female's mouth until hatching and brooding of the fry continues until the yolk sac is absorbed. Fry can swim freely in and out of the mother's mouth until the brooding period is completed in 1–2 weeks (Holden and Bruton, Reference Holden and Bruton1992; El-Sayed, Reference El-Sayed and El-Sayed2020).

Here, we explore several characteristics of hybrid tilapia infection by M. bejeranoi in fish ponds in northeastern Israel. First, we examined if the water of the earthen ponds where fertilization takes place and the fry spend the first 3 weeks of their lives contain actinospores, and if so, whether the fry can be infected this early in their lifecycle. Another important aspect in parasite–host relationship is host specificity. Although in some cases multiple related species are infected, Myxobolus parasites are highly host-specific and plasmodia develop mostly in specific tissues or organs (Molnár and Eszterbauer, Reference Molnár, Eszterbauer, Okamura, Gruhl and Bartholomew2015; Forró and Eszterbauer, Reference Forró and Eszterbauer2016). We were therefore interested to determine the specificity of M. bejeranoi to the hybrid tilapia by comparing infection rates to those of the parental purebred strains. To our knowledge, host specificity of hybrid fish vs its parental purebreds has not yet been studied in Myxozoa. Our study provides additional information on the capability of this myxozoan parasite in infecting its fish hosts.

Materials and methods

Study site

Research was carried out in earthen fishponds in the fish farms of Kibbutz Reshafim in northeastern Israel (32°28′53″N, 35°28′38″E; Fig. 1A). The rearing ponds (L, M, S in Fig. 1A) are 3 m deep and between 40 000 and 60 000 m2 in size. The ponds are supplied with water from the Hasi River through a circulation system and water salinity is about 1 ppt. At the bottom of the ponds, the thick sediment comprised a 4–5 cm layer of small-sized stones (0.5–1.5 cm in diameter) and then condensed mud. Fertilization ponds (12, 14, 16 in Fig. 1A) are situated in the same compound. Their characteristics are similar to those of the rearing ponds, except for their smaller size of approximately 5000 m2. Hybrid tilapia (Nile × blue tilapia) are cultured in the rearing ponds. The genetic diversity of the hybrids is unknown, because a variety of hybrids have been bred by the local aquaculture industry for many generations. Fish fertilization is carried out in 2–3 cycles during early summer by introducing males and females to the fertilization ponds. After 3 weeks, the fry are moved to a concrete pool, where they undergo hormonal sex reversal treatment using methyl testosterone for 3 weeks (Mojekwu, Reference Megbowon I and Mojekwu2014). Then, they are usually transferred to intermediate pools and after about 1 month, juvenile fish are placed in the rearing pond.

Fig. 1. Layout of fish farms in Reshafim, Israel, and design of purebred experiments. (A) A Google Earth shot of the fish farms in Kibbutz Reshafim in northeastern Israel (32°28′53″N, 35°28′38″E). Pond L, where purebred experiments were conducted, and the fertilization ponds 12, 16 and 17, where early infection experiments were performed, are indicated. (B) Purebred experimental design. Approximately 100 fish from each tilapia strain, namely Nile tilapia (Oreochromis niloticus), blue tilapia (O. aureus) and hybrid tilapia (Nile × blue), were exposed to pond water using 3 confined cages of ~100 L (100 × 30 × 30 cm3). After 1 week of exposure, fish were translocated to the Central Fish Health Laboratory, Nir David, to 100 L indoor aquarium tanks. Fish were sampled before exposure and at 0 and 33 days post-exposure (dpe). Gill tissue was sampled for DNA extraction and qPCR analysis and was fixed for histology.

Detection of waterborne actinospores

Water collection and filtration

Water samples were taken from fertilization pond 12 on 30 June and 13 July 2021. Water samples were filtered first through a 60 μm pore-size nitrocellulose membrane (Merck Millipore Ltd, NY6004700, MA, USA) and then through an 11 μm membrane (Merck Millipore Ltd, NY1104700, MA, USA). The first membrane filtered out much of the larger plankton and detritus, whereas the pore size of the second membrane was appropriate for trapping M. bejeranoi actinospores. The 11 μm membrane was collected after filtering 1–2 L of water, as 1 replicate, and was stored at −20°C for DNA extraction and polymerase chain reaction (PCR).

DNA extraction and PCR

Filter membrane was incubated with 1 mL of lysis buffer [40 mm ethylenediaminetetraacetic acid (EDTA), 50 mm Tris HCl (pH 8.3) and 0.75 M sucrose], 10 mg mL−1 of proteinase K and 10% sodium dodecyl sulfate (SDS) for 1 h at 55°C with occasional vortexing, as previously described (Massana et al., Reference Massana, Murray, Preston and DeLong1997), with minor modifications. Following phenol–chloroform–isoamyl alcohol phase separation steps, 1/10 volume of 3 M sodium acetate (pH 5.2) was added along with 2 volumes of ethanol. Following incubation for 20 min at −80°C and 15 min centrifugation at 4°C, DNA pellet was washed with 80% ethanol, and resuspended in PCR-grade water. PCR for detecting M. bejeranoi DNA was conducted using primers for M. bejeranoi small subunit ribosomal RNA gene (SSU rRNA; NCBI accession number MF401455; Mb 18S F186, Mb 18S R849) (Table S1) (Lövy et al., Reference Lövy, Smirnov, Brekhman, Ofek and Lotan2018). As a positive control, universal eukaryotic primers for 18S (Hadziavdic et al., Reference Hadziavdic, Lekang, Lanzen, Jonassen, Thompson and Troedsson2014) were amplified. PCR was performed in 25 μL volumes with 0.02 unit μL−1 of Phusion Hot Start Flex DNA Polymerase (Biolabs), 1× of Phusion HF 5× Buffer, 200 μM of deoxynucleoside triphosphates (dNTPs), 0.5 μM of forward and reverse primers and 1 μL (100–250 ng) of template. Denaturation of DNA (98°C for 5 min) was followed by 35 cycles of amplification (98°C for 10 s, 67°C for 10 s and 72°C for 30 s), and was ended by a 5 min extension (72°C). PCR products were run in a 1% agarose gel and the presence of actinospores was confirmed by a positive result for M. bejeranoi primers.

Early infection experiments

Collection of fish samples

Females and males were introduced to fertilization ponds 16 and 12 on 25 May and 14 June 2021, respectively (Table 1). On 14 June, about 3 weeks after the introduction of parents, fry were collected from pond 16 and then translocated to 100 L indoor aquarium tanks in the Central Fish Health Laboratory, Nir David. Samples were collected on 20 June and then again on 30 June. Fry from pond 12 were extracted from females’ mouths into buckets with clean water, and then translocated to aquarium tanks. Samples were collected on the day of collection on 30 June and then on 13 July and 23 August (Table 1). Additional samples from fertilization ponds were collected during summer 2022. Females and males were introduced to fertilization ponds 17 and 16 on 25 and 31 May 2022, respectively. On 14 June, fry were collected from pond 17, both from females’ mouths and from the pond water (0.008 g). On 22 June, pond 16 was sampled; and on 10 July, fry were collected from ponds 12 and 17 as a mixture (Table 1). Samples were treated with TRIzol reagent (ThermoFisher Scientific) and kept at −80°C or were fixed for in situ hybridization (ISH).

Table 1. Summary of the results of early-life Myxozoa infection experiments during 2021 and 2022 seasons

DNA extraction

DNA extraction was conducted using TRIzol reagent (ThermoFisher Scientific) according to the manufacturer's instructions, with minor modifications. To a 0.1 g of frozen sample, 1.5 mL of TRIzol was added and the tissue was homogenized using 4 3 mm glass beads (CS Chemicals Ltd) and a TissueLyser II (Qiagen) for 3 min at 30 Hz. Following incubation with chloroform (Sigma-Aldrich) and centrifugation for 15 min at 12 000 g, 4°C, the upper aqueous phase containing RNA was discarded, while the interphase and organic phases were utilized for DNA extraction. DNA quantification and purity were assessed using Nanodrop 2000c spectrophotometer (ThermoScientific).

Evaluation of infection severity by quantitative PCR

To detect low levels of M. bejeranoi DNA in fish gills, quantitative PCR (qPCR) was performed. Specific qPCR primers were utilized to amplify M. bejeranoi SSU rRNA gene (NCBI accession number MF401455) (Lövy et al., Reference Lövy, Smirnov, Brekhman, Ofek and Lotan2018) and tilapia β-actin gene was used as a normalizer gene (Zhou et al., Reference Zhou, Zhang, Xu, Yan, Yu, Wang, Xiao, Luo and Zhong2019) (Table S1) for the comparative ΔΔCTs method. qPCR was performed on 25 ng DNA as previously described (Maor-Landaw et al., Reference Maor-Landaw, Smirnov, Brekhman, Ofek-lalzar, Yahav and Lotan2022) and normalized expression levels were calculated.

Whole-mount in situ hybridization

For whole-mount ISH, an amplicon of 663 bp generated using M. bejeranoi SSU rRNA gene (primers Mb 18S F186, Mb 18S R849; Table S1) was cloned into pJET1.2/blunt cloning vector (ThermoFisher Scientific) and then transformed into competent bacteria by heat shock of 42°C for 1 min, followed by 4°C for 2 min. Bacteria were grown in liquid LB at 37°C overnight and plasmids were extracted using HiSpeed® Plasmid Midi Kit (Qiagen). A riboprobe was constructed by transcription of PCR products, with T7 promoter linked to the 3′ end of the amplicon, using MEGAscript kit (Ambion) and DIG RNA Labeling Mix kit (Roche). The product of in vitro transcription was treated with DNase and then purified and cleaned using NucleoSpin RNA cleanup (Macherey-Nagel).

ISH was performed on samples from fertilization ponds of 3–4-week-old fry collected on 10 July 2022, fry collected from females’ mouths on 14 June 2022 and 10-week-old fry collected from pond S on 3 August 2022. A gill sample of about a 3-month-old severely infected fish with developed cysts was obtained in August 2020 and preserved in 100% ethanol at −20°C following 24 h fixation with 4% paraformaldehyde.

Whole-mount ISH was performed following a previously reported protocol (Thisse and Thisse, Reference Thisse and Thisse2008), with some modifications. Whole fry were fixed in 4% paraformaldehyde for 24 h, followed by removal of pigmentation with hydrogen peroxide. Permeabilization was achieved by incubating with proteinase K (10 μg mL−1) for 30 min, and hybridization was accomplished in 60°C for 2–6 days with 1 μg mL−1 of probe (anti-sense and sense as a negative control). Anti-DIG antibody was diluted at 1/4000 with blocking solution.

Evaluating the infectious potential of the fish pond water

To assess the level of actinospores in the pond water, throughout the summer of 2021, naïve fish were placed in pond L in ~100 L cages (100 × 30 × 30 cm3) that were tailor-made of a PVC frame coated with a 5 mm sized mesh, allowing for free water flow from the pond. Fish were exposed to pond water for 1 day, and then euthanized with 1 mL L−1 of 2-phenoxyethanol (Sigma-Aldrich). Gills were sampled into TRIzol reagent (ThermoFisher Scientific), DNA was extracted and qPCR for M. bejeranoi SSU rRNA gene was conducted as detailed above. Water temperatures were recorded constantly using a temperature data logger (HOBO), and on August 2021, mean temperature was 30.25°C (s.d. ± 0.68).

Purebred experiments

Experimental layout

To assess host specificity of M. bejeranoi in infecting the hybrid, the 2 parental purebred tilapia species, along with the hybrid fish, were exposed to infectious pond water using 3 confined cages (as described above) for a 1-week period in August 2021. Each cage contained ~100 fish of the species blue tilapia (hatched on 8 June 2021; mean weight 3.04 g), Nile tilapia (hatched on 21 May; mean weight 2.94 g) or Nile × blue tilapia hybrid (hatched on 31 June; mean weight 2.98 g). Before exposure, 5 representative fish of each species were screened and found negative for pathogens. After exposure, fish were translocated to 100 L indoor aquarium tanks in the Central Fish Health Laboratory (Fig. 1B). Tanks had a flow-through system with dechlorinated tap water at a temperature of ~25°C. Fish were fed daily with commercial pellets.

Collection of fish samples, DNA extraction and qPCR

Experimental exposed fish were sampled at 0 and 33 days post-exposure (dpe) (10 < n < 30). Unexposed control fish were collected before the beginning of the experiment (11 < n < 15). Fish gills were sampled as described above. DNA was extracted using TRIzol reagent and followed by qPCR, as described above.

Histology analysis

Gills dissected from hybrid, Nile and blue tilapia were fixed in 10% neutral-buffered formalin, dehydrated in a graded ethanol series and embedded in 2-hydroxyethyl methacrylate. Then, 3 μm-thick sections were generated using a Leica RM 2245 microtome. Sections were stained with haematoxylin and eosin according to standard protocol.

Statistical analysis

Normal distribution was tested by Shapiro–Wilk test and data that were not normally distributed were tested for significance using Mann–Whitney non-parametric test (SPSS software v. 27). Statistical significance was defined as P < 0.05.

Results

To determine if hybrid tilapia at early-life stages can be infected by M. bejeranoi, we examined fish fry of different lifecycle stages from fertilization and rearing ponds in commercial fish farms of Kibbutz Reshafim (Fig. 1A) during 2 consecutive summers. We collected fry that have completed metamorphosis and brooding period and swam freely in the pond water, as well as fry that were extracted from female mouths, at post-larva stage some still bearing their yolk sac to some extent (Ismarica et al., Reference Ismarica, Fazriansyah Putra and Khairina2022).

In the first season, the summer of 2021, fry that had been collected from pond 16 were analysed by qPCR 6 and 16 days later (20 and 30 June; Table 1). Results showed 70 and 80% of infection in the first and second sampling points, respectively (Table 1). By contrast, in the fry of mixed developmental stages collected from 4 females’ mouths 2 weeks after introducing males and females to fertilization pond 12 (30 June), no infection was detected (Table 1). To corroborate this result, additional individuals were kept in aquarium tanks in clean flow water system and were re-examined twice, after 2 weeks and after a month, with no indication for infection. Notably, PCR analysis of water collected from fertilization pond 12 on both sampling occasions (30 June and 13 July) showed the presence of waterborne actinospores (Table 1).

In the second season, during early summer 2022, we sought to validate the infection of hybrid tilapia fry by M. bejeranoi shown in the 2021 trials. We found in 3 different fertilization cycles that indeed fry which are less than 3 weeks old are infected with the parasite and that the percentage of infection increased during the season (Table 1). Additionally, we repeated the analysis of fry at early developmental stages extracted directly from females’ mouths (on 14 June) 3 weeks after introducing males and females to fertilization pond 17 (Table 1). Results showed that while 33% of the fry sampled from the water of the same pond at the same time point were infected, brooding fry were not.

To visualize the early onset of infection, we performed whole-mount ISH with a specific probe targeting M. bejeranoi SSU rRNA gene. Results showed specific staining in the gills of 3–4-week-old infected fry (Fig. 2A). The analysis of older fry at 10 weeks of age revealed developing cysts (Fig. 2B), which later produced myxospores (Fig. 2C and D). No staining was apparent in control samples hybridized with the sense probe (Fig. 2E) or in fry collected from female's mouths hybridized with the anti-sense probe (Fig. 2F).

Fig. 2. Whole-mount in situ hybridization for M. bejeranoi SSU rRNA shows infection progression. (A) Early infection of 3–4-week-old fry. Bar, 50 μm. (B) Cysts at different developmental stages (mark with arrows) in 6-week-old fry. Bar, 100 μm. (C) A cyst full of spores at an advanced infection stage in ~3-month-old juveniles. Bar, 50 μm. (D) A close up of mature cysts with spores (mark with arrows). Bar, 20 μm. (E) Sense control in 6-week-old fry. Bar, 50 μm. (F) Non-infected control fry collected from females’ mouths. Bar, 100 μm.

These results indicate that the water of the fertilization ponds, in which new generations of cultured hybrid tilapia are hatched, contain M. bejeranoi actinospores that may infect young fry. We therefore proceeded to evaluate infection dynamics in the rearing ponds using fish that had been extracted from females’ mouths in fertilization pond 12 (on 14 June 2021), which were clear of myxozoan infection. Those naïve juveniles (0.24 g) were exposed to the water of pond L at 3 time points in August 2021 for 24 h, using cages. As determined by qPCR (Fig. 3), relative infection severity increased gradually demonstrating significant change (P < 0.05 Mann–Whitney test). Additionally, on July 13, actinospores were detected in the pond water.

Fig. 3. Normalized infection severity of hybrid tilapia in pond L during August 2021 following a 24 h exposure to pond water (9 < n < 15). Asterisks indicate statistically significant differences between the groups (P < 0.05 Mann–Whitney test). Percentages of infected fish are indicated above the bars.

Having established that the water of pond L is infectious (Fig. 3), we exposed the 2 parental purebred species, Nile and blue tilapia, alongside the hybrid tilapia, to the pond water for 1 week. The analysis of exposed fish at the end of the week revealed minor parasitic load in all 3 species (Fig. 4A). However, 33 days later, differences in infection patterns were observed. Whereas infection severity in blue and hybrid tilapia was similarly high, in Nile tilapia, copy numbers remained very low. Both blue and hybrid tilapia infection states after 33 days differed significantly from those of Nile tilapia (P < 0.05 Mann–Whitney test) (Fig. 4B). These differences in susceptibility to M. bejeranoi infection were further verified by histological analysis, which showed plasmodia formation in the gills of blue and hybrid tilapia, but not of Nile tilapia (Fig. 4).

Fig. 4. Progression of M. bejeranoi infection in 3 tilapia species. (A, B) Normalized qPCR analysis results for expression of M. bejeranoi SSU rRNA in Nile, blue and hybrid tilapia at 0 dpe (A) and 33 dpe (B) after a 1-week exposure to the pond water (11 < n < 15 for each fish species and time point). At 0 dpe, all 3 fish species displayed low levels of infection. At 33 dpe, there is a significant increase of infection level (P < 0.05 Mann–Whitney test) in either blue or hybrid compared to Nile tilapia. In uninfected control fish, infection levels were 0 (data not shown). The results are normalized to tilapia β-actin. (C–H) Histological sections show cyst-free tissue in Nile tilapia (C, D) and cyst development (marked with arrow) in blue tilapia (E, F) and hybrid tilapia (G, H). Bars in C, E and G are 50 μm and in D, F and H 20 μm.

Discussion

In this study, we addressed several gaps in knowledge in the relationship between M. bejeranoi and cultured tilapia fish. In Israel, intensive aquaculture systems contain several pond types and fish are transferred from one pond to another. Thus, characterizing infection dynamics in the various ponds is important for a better understanding of the infection mechanism, as well as for planning and operating these facilities.

Infection rates in the fish pond labelled L peaked during August, as we observed in pond M in our previous study (Maor-Landaw et al., Reference Maor-Landaw, Smirnov, Brekhman, Ofek-lalzar, Yahav and Lotan2022). This result is not surprising, as many studies have linked myxozoan infection with seasonal increase in temperatures (Schmidt-Posthaus and Wahli, Reference Schmidt-Posthaus, Wahli, Okamura and Gruhl2015). Myxobolus bejeranoi actinospores were found not only in the larger rearing ponds, but also in the fertilization ponds, where new offspring are generated in several cycles each season and where the sediment layout is similar. Furthermore, here we show that M. bejeranoi actinospores are capable of infecting hybrid tilapia fry. Given that the hatching and brooding period lasts 1–2 weeks (El-Sayed, Reference El-Sayed and El-Sayed2020), the collected fry were only 3 weeks of age or younger. Ontogeny studies have shown that both blue and Nile tilapia complete metamorphosis in 15 days, when the yolk sac is absorbed (Holden and Bruton, Reference Holden and Bruton1992; Fishelson and Bresler, Reference Fishelson and Bresler2002). Thus, the fry that were infected by M. bejeranoi should have already developed gills, which are targeted by the parasite. Prior to their release from the female's mouth, brooding fry have the opportunity to swim out into the water (Lowe, Reference Lowe1955). Thus, fry obtained from females’ mouths were exposed to M. bejeranoi actinospores, but they were not infected. This could be due to underdeveloped gill lamellae (Holden and Bruton, Reference Holden and Bruton1992), or because of less exposure to the pond water.

There are several indications for myxozoan infection of fish larvae. The earliest reported infection that we found is of fry at about 1 month of age, which were infected by Thelohanellus wuhanensis (Wang et al., Reference Wang, Yao, Wang and Lu2001). Myxobolus cerebralis, which is associated with the destruction of cartilage in juvenile salmonids, can infect fish at 7 weeks post-hatching (Ryce et al., Reference Ryce, Zale, Macconnell and Nelson2005; Eszterbauer et al., Reference Eszterbauer, Atkinson, Diamant, Morris, El-Matbouli, Hartikainen, Okamura, Gruhl and Bartholomew2015). Additional myxozoan species that infect juvenile fish are Tetracapsuloides bryosalmonae, Henneguya ictaluri (Fontes et al., Reference Fontes, Hallett, Atle Mo, Okamura, Gruhl and Bartholomew2015), Thelohanellus wangi (Yuan et al., Reference Yuan, Xi, Wang, Xie and Zhang2015) and Gadimyxa atlantica (Holzer et al., Reference Holzer, Stewart, Tildesley, Wootten and Sommerville2010).

Fish at early-life stages are protected by a combination of passive immunity, transmitted from maternal sources, and innate immunity components, that include immunoglobulins, complement factors, lysozymes, protease inhibitors, lectins and serine proteases-like molecules (Swain and Nayak, Reference Swain and Nayak2009). This transition phase, after which the defence system becomes more adaptive-governed and eventually a fully responsive immunity, may last several weeks, depending on species and environmental conditions (Zapata et al., Reference Zapata, Diez, Cejalvo, Gutiérrez-De Frías and Cortés2006). These circumstances render the fry more vulnerable to pathogens. Moreover, the direct contact of the gills with the pond water when the immune system is yet to be fully developed and responsive may facilitate the entry invasion of parasites such as M. bejeranoi (Vadstein et al., Reference Vadstein, Bergh, Gatesoupe, Galindo-Villegas, Mulero, Picchietti, Scapigliati, Makridis, Olsen, Dierckens, Defoirdt, Boon, De Schryver and Bossier2013). Our results indicate that when juveniles are transferred into the larger ponds, where most of their growth occurs, they may already be infected with the parasite. In the large rearing pond, where the fish spend several months, more fish–actinospore encounters are likely to happen, which would result in increased parasite load in the fish's gills. Ultimately, an immune-compromised individual will continuously be challenged by various opportunistic pathogens (Maor-Landaw et al., Reference Maor-Landaw, Smirnov, Brekhman, Ofek-lalzar, Yahav and Lotan2022).

Hybrid tilapia are the second most cultured strain of tilapia in the world and are the main strain in Israel (Miao and Wang, Reference Miao and Wang2020). The natural distribution of Nile and blue tilapia largely overlaps in Africa and the Middle East, but hybridization was never documented in the wild (Rognon and Guyomard, Reference Rognon and Guyomard2003). However, given the high host specificity of Myxobolus species (Molnár and Eszterbauer, Reference Molnár, Eszterbauer, Okamura, Gruhl and Bartholomew2015), we investigated infection patterns in the 2 parental species, Nile and blue tilapia. Fish hybridization through interspecific breeding is exploited in aquaculture to produce offspring with improved traits (Hulata, Reference Hulata2001). Hybrid tilapia of Nile females and blue males is characterized by greater tolerance to cold and salinity (Hulata, Reference Hulata2001), improved growth performance and haematological metabolic indices and higher survival rates (Xiao et al., Reference Xiao, Chen, Wang, Zou, Wang, Li, Zhu, Yu and Yang2022). The hybrid growth vigour is supported by higher expression of growth hormone and insulin-like growth factor 1, compared to its parental species (Zhong et al., Reference Zhong, Zhang, Xu, Yan, Han, Zheng, Xiao, Tang, Wang, Luo and Zhou2019; Zhou et al., Reference Zhou, Zhang, Xu, Yan, Yu, Wang, Xiao, Luo and Zhong2019).

Hybrid tilapia is an example for heterosis, which is hybridization between different strains that produces an offspring with a superior phenotype and fitness (Chen, Reference Chen2013). Heterosis has played a major role in shaping genetic variation that can be recombined and sorted into many new species when presented with the ecological opportunity, as was shown for haplochromine cichlid fishes of Lake Victoria (Meier et al., Reference Meier, Marques, Mwaiko, Wagner, Excoffier and Seehausen2017). Thus, hybridization can also generate new habitats and niches for parasites (Krasnovyd et al., Reference Krasnovyd, Vetešník, Gettová, Civán and Šimková2017). For example, cyprinid hybrids were shown to harbour more parasite species as compared to their parental species. However, parasite abundance was lower (Šimková et al., Reference Šimková, Dávidová, Papoušek and Vetešník2013; Krasnovyd et al., Reference Krasnovyd, Vetešník, Gettová, Civán and Šimková2017), supporting an advantage of these heterotic hybrids in immune resilience (Cnaani et al., Reference Cnaani, Tinman, Avidar, Ron and Hulata2004; Šimková et al., Reference Šimková, Vojtek, Halacka, Hyrsl and Vetesnik2015; Griffin et al., Reference Griffin, Ware, Rosser, Woodyard, Mischke, Byars and Wise2020; Šimkova et al., Reference Šimkova, Janác, Hyrsl, Krasnovyd and Vetesnik2021).

Nonetheless, hybrids were documented to display susceptibility to different parasitic species (Krasnovyd et al., Reference Krasnovyd, Vetešník, Gettová, Civán and Šimková2017). Indeed, when hybrid tilapia was exposed to M. bejeranoi, it exhibited high susceptibility and a progressed infection after 1 month. Our results show that the susceptibility of hybrid tilapia and its parental species Nile and blue tilapia to M. bejeranoi is of a non-additive nature, meaning the hybrid is not an intermediate between the parental species (Chen, Reference Chen2013). These results are in accordance with the dominance scenario, which was coined by Fritz et al. to describe a hybrid whose susceptibility is similar to that of one of its parental taxa (Fritz et al., Reference Fritz, Nichols and Brunsfeld1994).

Recently, we have demonstrated in a transcriptomic analysis that M. bejeranoi represses the immune system of its hybrid tilapia host by downregulating key immune-related genes, allowing for its efficient proliferation (Maor-Landaw et al., Reference Maor-Landaw, Smirnov, Brekhman, Ofek-lalzar, Yahav and Lotan2022). Whether blue tilapia infected with M. bejeranoi also undergoes immune suppression is yet to be tested by compared gene-expression patterns with the resilient Nile tilapia. Thus, the genetic mechanism underlying the resilience pattern (Fritz et al., Reference Fritz, Hochwender, Brunsfeld and Roche2003) presented here is unclear and was not within the scope of this study. Future studies should deploy omics tools along with epigenetics approaches and comprehensive quantitative trait locus-based phenotyping (Lippman and Zamir, Reference Lippman and Zamir2006; Chen, Reference Chen2013; Shen et al., Reference Shen, Sun, Hua, Shen, Ye, Cai, Timko, Zhu and Fan2017; Xiao et al., Reference Xiao, Chen, Wang, Zou, Wang, Li, Zhu, Yu and Yang2022) to uncover possible allelic interactions between parental genomes and altered programming of genes, which would shed light on the molecular apparatus that governs this phenomenon.

In summary, in this study, we show a novel early-life infection of hybrid tilapia with M. bejeranoi occurring already less than 3 weeks after fertilization, while fry are still in the fertilization ponds. Additionally, M. bejeranoi can also infect one of the hybrid's parental species, blue tilapia, with high prevalence that is similar to that of the hybrid. These findings open new questions regarding the mechanism allowing the parasite to distinguish the suitable host from a closely related species, and be organ-specific at very early-life stages.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0031182023000240.

Data availability

The authors confirm that the data supporting the findings of this study are available within the article. Raw data are available from the corresponding and first author.

Acknowledgements

The authors are grateful to Reuven Godel from Reshafim Pisciculture for his tremendous help with the pond fish and assistance with the cage experiments. The authors thank Benny Ron from the Central Fish Health Laboratory, Nir David, Israel, and Alon Naor and Shay Lev-Tenne from Dor Aquaculture Research Station, for their assistance with obtaining the fish strains. The authors also thank Tal Gafni for her assistance with the statistics and Maya Ofek-Lalzar from the bioinformatics unit of the University of Haifa for consultation and advice.

Author's contribution

K. M.-L. and T. L. conceived and designed the study. K. M.-L., I. A., B. S., M. S., V. B. and T. L. performed the experiments. K. M.-L., I. A., B. S. and T. L. analysed the data. K. M.-L. and T. L. wrote the manuscript. All authors have read and agreed to the published version of the manuscript.

Financial support

This research was funded by the Israel Science Foundation, grant number 297/19, by research grant number IS-5465-22CR from BARD, the United States-Israel Binational Agricultural and by the United States-Israel Binational Science Foundation (BSF), Jerusalem, Israel grant number 2019063. K. M.-L. was funded by the University of Haifa post-doc fellowship.

Conflict of interest

None.

Ethical standards

All applicable international, national and/or institutional guidelines for the care and use of animals were followed and the study design was approved (permit 652/19) by the Animal Ethics and Welfare Committee of the University of Haifa, Israel.

References

Atkinson, SD, Bartholomew, JL and Lotan, T (2018) Myxozoans: ancient metazoan parasites find a home in phylum Cnidaria. Zoology 129, 6668.10.1016/j.zool.2018.06.005CrossRefGoogle ScholarPubMed
Chen, ZJ (2013) Genomic and epigenetic insights into the molecular bases of heterosis. Nature Publishing Group 14, 471482.Google ScholarPubMed
Cnaani, A, Tinman, S, Avidar, Y, Ron, M and Hulata, G (2004) Comparative study of biochemical parameters in response to stress in Oreochromis aureus, O. mossambicus and two strains of O. niloticus. Aquaculture Research 35, 14341440.10.1111/j.1365-2109.2004.01167.xCrossRefGoogle Scholar
Eknath, AE and Hulata, G (2009) Use and exchange of genetic resources of Nile tilapia (Oreochromis niloticus). Reviews in Aquaculture 1, 197213.10.1111/j.1753-5131.2009.01017.xCrossRefGoogle Scholar
El-Sayed, A-FM (2020) Chapter 8 – Reproduction and seed production. In El-Sayed, A-FM (ed.), Tilapia Culture, 2nd Edn. Academic Press, pp. 173–203. https://doi.org/10.1016/B978-0-12-816509-6.00008-2.Google Scholar
Eszterbauer, E, Atkinson, S, Diamant, A, Morris, D, El-Matbouli, M and Hartikainen, H (2015) Myxozoan life cycles: practical approaches and insights. In Okamura, B, Gruhl, A and Bartholomew, J (eds), Myxozoan Evolution, Ecology and Development. Cham: Springer, pp. 175198.10.1007/978-3-319-14753-6_10CrossRefGoogle Scholar
Fishelson, L and Bresler, V (2002) Comparative studies of the development and differentiation of chloride cells in tilapine fish with different reproductive styles. Journal of Morphology 253, 118131.10.1002/jmor.1115CrossRefGoogle ScholarPubMed
Fontes, I, Hallett, SL and Atle Mo, T (2015) Comparative epidemiology of myxozoan diseases. In Okamura, B, Gruhl, A and Bartholomew, JL (eds), Myxozoan Evolution, Ecology and Development. Cham: Springer, pp. 317341.10.1007/978-3-319-14753-6_17CrossRefGoogle Scholar
Forró, B and Eszterbauer, E (2016) Correlation between host specificity and genetic diversity for the muscle-dwelling fish parasite Myxobolus pseudodispar: examples of myxozoan host-shift? Folia Parasitologica 63, 18.10.14411/fp.2016.019CrossRefGoogle ScholarPubMed
Fritz, RS, Nichols, CM and Brunsfeld, SJ (1994) Interspecific hybridization of plants and resistance to herbivores: hypotheses, genetics, and variable responses in a diverse herbivore community. Oecologia, 97, 106117.10.1007/BF00317914CrossRefGoogle Scholar
Fritz, RS, Hochwender, CG, Brunsfeld, SJ and Roche, BM (2003) Genetic architecture of susceptibility to herbivores in hybrid willows. Journal of Evolutionary Biology 16, 11151126.10.1046/j.1420-9101.2003.00617.xCrossRefGoogle ScholarPubMed
Gilbert, MA and Granath, WO (2001) Persistent infection of Myxobolus cerebralis, the causative agent of salmonid whirling disease, in Tubifex tubifex. Journal of Parasitology 87, 101107.10.1645/0022-3395(2001)087[0101:PIOMCT]2.0.CO;2CrossRefGoogle ScholarPubMed
Griffin, MJ, Ware, C, Rosser, TG, Woodyard, ET, Mischke, CC, Byars, TS and Wise, DJ (2020) Monoculture of ♀ channel (Ictalurus punctatus) × ♂ blue (I. furcatus) hybrid catfish mitigates proliferative gill disease caused by Henneguya ictaluri (Cnidaria: Myxobolidae) in catfish aquaculture ponds. Journal of the World Aquaculture Society 51, 729739.10.1111/jwas.12695CrossRefGoogle Scholar
Hadziavdic, K, Lekang, K, Lanzen, A, Jonassen, I, Thompson, EM and Troedsson, C (2014) Characterization of the 18S rRNA gene for designing universal eukaryote specific primers. PLoS ONE 9, e87624.10.1371/journal.pone.0087624CrossRefGoogle ScholarPubMed
Holden, KK and Bruton, MN (1992) A life-history approach to the early ontogeny of the Mozambique tilapia Oreochromis mossambicus (Pisces, Cichlidae). South African Journal of Zoology 27, 173191.10.1080/02541858.1992.11448279CrossRefGoogle Scholar
Holzer, AS, Stewart, S, Tildesley, A, Wootten, R and Sommerville, C (2010) Infection dynamics of two renal myxozoans in hatchery reared fry and juvenile Atlantic cod Gadus morhua L. Parasitology 137, 15011513.10.1017/S0031182010000247CrossRefGoogle ScholarPubMed
Holzer, AS, Barto, P, Born-torrijos, A, Alena, L, Hartigan, A and Fiala, I (2018) The joint evolution of the Myxozoa and their alternate hosts: a cnidarian recipe for success and vast biodiversity. Molecular Ecology 27, 16511666.10.1111/mec.14558CrossRefGoogle ScholarPubMed
Hulata, G (2001) Genetic manipulations in aquaculture: a review of stock improvement by classical and modern technologies. Genetica 111, 155173.10.1023/A:1013776931796CrossRefGoogle ScholarPubMed
Hulata, G (2014) Tilapias-Biology and Culture. Israel: Ma'arechet Publishing House.Google Scholar
Ismarica, I, Fazriansyah Putra, D and Khairina, U (2022) Ontogeny and morphological development of Tilapia (Oreochromis niloticus) larvae in Aceh Province, Indonesia. E3S Web of Conferences 339, 01007.10.1051/e3sconf/202233901007CrossRefGoogle Scholar
Kent, M, Margolis, L and Corliss, J (1994) The demise of a class of protists: taxonomic and nomenclatural revisions proposed for the protist phylum Myxozoa Grasse, 1970. Canadian Journal of Zoology 72, 932937.10.1139/z94-126CrossRefGoogle Scholar
Krasnovyd, V, Vetešník, L, Gettová, L, Civán, K and Šimková, A (2017) Patterns of parasite distribution in the hybrids of non-congeneric cyprinid fish species: is asymmetry in parasite infection the result of limited coadaptation? International Journal for Parasitology 47, 471483.10.1016/j.ijpara.2017.01.003CrossRefGoogle ScholarPubMed
Lippman, ZB and Zamir, D (2006) Heterosis: revisiting the magic. Trends in Genetics 23, 6066.10.1016/j.tig.2006.12.006CrossRefGoogle ScholarPubMed
Lövy, A, Smirnov, M, Brekhman, V, Ofek, T and Lotan, T (2018) Morphological and molecular characterization of a novel myxosporean parasite Myxobolus bejeranoi n. sp. (Cnidaria: Myxosporea) from hybrid tilapia in Israel. Parasitology Research 117, 491499.10.1007/s00436-017-5725-2CrossRefGoogle Scholar
Lowe, RH (1955) The fecundity of tilapia species. The East African Agricultural Journal 21, 4552.10.1080/03670074.1955.11665004CrossRefGoogle Scholar
Maor-Landaw, K, Smirnov, M, Brekhman, V, Ofek-lalzar, M, Yahav, T and Lotan, T (2022) Infection by the Parasite Myxobolus bejeranoi (Cnidaria: Myxozoa) suppresses the immune system of hybrid tilapia. Microorganisms 10, 119.10.3390/microorganisms10101893CrossRefGoogle ScholarPubMed
Massana, R, Murray, AE, Preston, CM and DeLong, EF (1997) Vertical distribution and phylogenetic characterization of marine planktonic archaea in the Santa Barbara Channel. Microbiology 63, 5056.Google ScholarPubMed
Megbowon I, and Mojekwu, TO (2014) Tilapia sex reversal using methyl testosterone (MT) and its effect on fish. Man and Environment. Biotechnology 13, 213216.Google Scholar
Meier, JI, Marques, DA, Mwaiko, S, Wagner, CE, Excoffier, L and Seehausen, O (2017) Ancient hybridization fuels rapid cichlid fish adaptive radiations. Nature Communications 8, 111.10.1038/ncomms14363CrossRefGoogle ScholarPubMed
Miao, W and Wang, W (2020) Trends of aquaculture production and trade: carp, tilapia, and shrimp. Asian Fisheries Science 33, 110.Google Scholar
Milstein, A, Zoran, M, Kochba, M and Avnimelech, Y (2001) Effect of different management practices on water quality of intensive tilapia culture systems in Israel. Aquaculture International 9, 133152.10.1023/A:1014209124855CrossRefGoogle Scholar
Molnár, K and Eszterbauer, E (2015) Specificity of infection sites in vertebrate hosts. In Okamura, B, Gruhl, A and Bartholomew, J (eds), Myxozoan Evolution, Ecology and Development. Switzerland: Springer, pp. 295316.10.1007/978-3-319-14753-6_16CrossRefGoogle Scholar
Rognon, X and Guyomard, R (2003) Large extent of mitochondrial DNA transfer from Oreochromis aureus to O. niloticus in West Africa. Molecular Ecology 12, 435445.10.1046/j.1365-294X.2003.01739.xCrossRefGoogle Scholar
Ryce, EKN, Zale, AV, Macconnell, E and Nelson, M (2005) Effects of fish age versus size on the development of whirling disease in rainbow trout. Diseases of Aquatic Organisms 63, 6976.10.3354/dao063069CrossRefGoogle ScholarPubMed
Schmidt-Posthaus, H and Wahli, T (2015) Host and environmental influences on development of disease. In Okamura, B and Gruhl, A (eds), Myxozoan Evolution, Ecology and Development. Cham: Springer, pp. 281293.10.1007/978-3-319-14753-6_15CrossRefGoogle Scholar
Shen, Y, Sun, S, Hua, S, Shen, E, Ye, C, Cai, D, Timko, MP, Zhu, Q and Fan, L (2017) Analysis of transcriptional and epigenetic changes in hybrid vigor of allopolyploid Brassica napus uncovers key roles for small RNAs. The Plant Journal 91, 874893.10.1111/tpj.13605CrossRefGoogle ScholarPubMed
Šimková, A, Dávidová, M, Papoušek, I and Vetešník, L (2013) Does interspecies hybridization affect the host specificity of parasites in cyprinid fish? Parasites & Vectors 6, 110.10.1186/1756-3305-6-95CrossRefGoogle ScholarPubMed
Šimková, A, Vojtek, L, Halacka, K, Hyrsl, P and Vetesnik, L (2015) The effect of hybridization on fish physiology, immunity and blood biochemistry: a case study in hybridizing Cyprinus carpio and Carassius gibelio (Cyprinidae). Aquaculture 435, 381389.10.1016/j.aquaculture.2014.10.021CrossRefGoogle Scholar
Šimkova, A, Janác, M, Hyrsl, P, Krasnovyd, V and Vetesnik, L (2021) Vigour-related traits and immunity in hybrids of evolutionary divergent cyprinoid species: advantages of hybrid heterosis? Journal of Fish Biology 98, 11551171.10.1111/jfb.14648CrossRefGoogle ScholarPubMed
Swain, P and Nayak, SK (2009) Role of maternally derived immunity in fish. Fish and Shellfish Immunology 27, 8999.10.1016/j.fsi.2009.04.008CrossRefGoogle ScholarPubMed
Thisse, C and Thisse, B (2008) High-resolution in situ hybridization to whole-mount zebrafish embryos. Nature Protocols 3, 5969.10.1038/nprot.2007.514CrossRefGoogle ScholarPubMed
Vadstein, O, Bergh, Ø, Gatesoupe, FJ, Galindo-Villegas, J, Mulero, V, Picchietti, S, Scapigliati, G, Makridis, P, Olsen, Y, Dierckens, K, Defoirdt, T, Boon, N, De Schryver, P and Bossier, P (2013) Microbiology and immunology of fish larvae. Reviews in Aquaculture 5, S1S25.10.1111/j.1753-5131.2012.01082.xCrossRefGoogle Scholar
Wang, GT, Yao, WJ, Wang, JG and Lu, YS (2001) Occurrence of thelohanellosis caused by Thelohanellus wuhanensis (Myxosporea) in juvenile allogynogenetic silver crucian carp, Carassius auratus gibelio (Bloch), with an observation on the efficacy of fumagillin as a therapeutant. Journal of Fish Diseases 24, 5760.10.1046/j.1365-2761.2001.00269.xCrossRefGoogle Scholar
Wolf, K and Markiw, ME (1984) Biology contravenes taxonomy in the Myxozoa: new discoveries show alternation of invertebrate and vertebrate hosts. Science 225, 14491452.10.1126/science.225.4669.1449CrossRefGoogle ScholarPubMed
Xiao, W, Chen, B, Wang, J, Zou, Z, Wang, C, Li, D, Zhu, J, Yu, J and Yang, H (2022) Integration of mRNA and miRNA profiling reveals heterosis in Oreochromis niloticus×O. aureus hybrid tilapia. Animals 12, 122.10.3390/ani12050640CrossRefGoogle Scholar
Yuan, S, Xi, BW, Wang, JG, Xie, J and Zhang, JY (2015) Thelohanellus wangi n. sp. (Myxozoa, Myxosporea), a new gill parasite of allogynogenetic gibel carp (Carassius auratus gibelio Bloch) in China, causing severe gill myxosporidiosis. Parasitology Research 114, 3745.10.1007/s00436-014-4157-5CrossRefGoogle Scholar
Zapata, A, Diez, B, Cejalvo, T, Gutiérrez-De Frías, C and Cortés, A (2006) Ontogeny of the immune system of fish. Fish and Shellfish Immunology 20, 126136.10.1016/j.fsi.2004.09.005CrossRefGoogle ScholarPubMed
Zhong, H, Zhang, X, Xu, Q, Yan, J, Han, Z, Zheng, H, Xiao, J, Tang, Z, Wang, F, Luo, Y and Zhou, Y (2019) Nonadditive and asymmetric allelic expression of growth hormone in hybrid tilapia. Frontiers in Genetics 10, 111.10.3389/fgene.2019.00961CrossRefGoogle ScholarPubMed
Zhou, Y, Zhang, X, Xu, Q, Yan, J, Yu, F, Wang, F, Xiao, J, Luo, Y and Zhong, H (2019) Nonadditive and allele-specific expression of insulin-like growth factor 1 in Nile tilapia (Oreochromis niloticus, ♀) × blue tilapia (O. aureus, ♂) hybrids. Comparative Biochemistry and Physiology Part – B: Biochemistry and Molecular Biology 232, 93100.10.1016/j.cbpb.2019.03.002CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1. Layout of fish farms in Reshafim, Israel, and design of purebred experiments. (A) A Google Earth shot of the fish farms in Kibbutz Reshafim in northeastern Israel (32°28′53″N, 35°28′38″E). Pond L, where purebred experiments were conducted, and the fertilization ponds 12, 16 and 17, where early infection experiments were performed, are indicated. (B) Purebred experimental design. Approximately 100 fish from each tilapia strain, namely Nile tilapia (Oreochromis niloticus), blue tilapia (O. aureus) and hybrid tilapia (Nile × blue), were exposed to pond water using 3 confined cages of ~100 L (100 × 30 × 30 cm3). After 1 week of exposure, fish were translocated to the Central Fish Health Laboratory, Nir David, to 100 L indoor aquarium tanks. Fish were sampled before exposure and at 0 and 33 days post-exposure (dpe). Gill tissue was sampled for DNA extraction and qPCR analysis and was fixed for histology.

Figure 1

Table 1. Summary of the results of early-life Myxozoa infection experiments during 2021 and 2022 seasons

Figure 2

Fig. 2. Whole-mount in situ hybridization for M. bejeranoi SSU rRNA shows infection progression. (A) Early infection of 3–4-week-old fry. Bar, 50 μm. (B) Cysts at different developmental stages (mark with arrows) in 6-week-old fry. Bar, 100 μm. (C) A cyst full of spores at an advanced infection stage in ~3-month-old juveniles. Bar, 50 μm. (D) A close up of mature cysts with spores (mark with arrows). Bar, 20 μm. (E) Sense control in 6-week-old fry. Bar, 50 μm. (F) Non-infected control fry collected from females’ mouths. Bar, 100 μm.

Figure 3

Fig. 3. Normalized infection severity of hybrid tilapia in pond L during August 2021 following a 24 h exposure to pond water (9 < n < 15). Asterisks indicate statistically significant differences between the groups (P < 0.05 Mann–Whitney test). Percentages of infected fish are indicated above the bars.

Figure 4

Fig. 4. Progression of M. bejeranoi infection in 3 tilapia species. (A, B) Normalized qPCR analysis results for expression of M. bejeranoi SSU rRNA in Nile, blue and hybrid tilapia at 0 dpe (A) and 33 dpe (B) after a 1-week exposure to the pond water (11 < n < 15 for each fish species and time point). At 0 dpe, all 3 fish species displayed low levels of infection. At 33 dpe, there is a significant increase of infection level (P < 0.05 Mann–Whitney test) in either blue or hybrid compared to Nile tilapia. In uninfected control fish, infection levels were 0 (data not shown). The results are normalized to tilapia β-actin. (C–H) Histological sections show cyst-free tissue in Nile tilapia (C, D) and cyst development (marked with arrow) in blue tilapia (E, F) and hybrid tilapia (G, H). Bars in C, E and G are 50 μm and in D, F and H 20 μm.

Supplementary material: PDF

Maor-Landaw et al. supplementary material

Table S1

Download Maor-Landaw et al. supplementary material(PDF)
PDF 64.4 KB