Effects of clioquinol on the scuticociliatosis-causing protozoan Miamiensis avidus in olive flounder Paralichthys olivaceus

A practical guide to necropsy of the elasmobranch chondrocranium and causes of mortality in wild and aquarium-housed California elasmobranchs

Elasmobranchs are common, iconic species in public aquaria; their wild counterparts are key members of marine ecosystems. Post-mortem examination is a critical tool for disease monitoring of wild elasmobranchs and for management of those under human care. Careful necropsy of the head, with a focus on clinically relevant anatomy, can ensure that proper samples are collected, increasing the chance of presumptive diagnoses prior to slower diagnostic workup. Immediate feedback from a thorough head necropsy allows for faster management decisions, often identifying pathogens, routes of pathogen entry, and pathogenesis, which are current shortcomings in published literature. This article proposes a protocol for necropsy of the elasmobranch chondrocranium, emphasizing unique anatomy and careful dissection, evaluation, and sampling of the endolymphatic pores and ducts, inner ears, brain, and olfactory system as part of a complete, whole-body necropsy. Extensive use of cytology and microbiology, along with thorough sample collection for histology and molecular biology, has proven effective in identifying a wide range of pathogens and assisting with characterization of pathogenesis. The cause of mortality is often identified from a head necropsy alone, but does not replace a thorough whole-body dissection. This protocol for necropsy and ancillary diagnostic sample collection and evaluation was developed and implemented in the necropsy of 189 wild and aquarium-housed elasmobranchs across 18 species over 13 years (2011-2023) in California. Using this chondrocranial approach, meningoencephalitis was determined to be the primary cause of mortality in 70% (118/168) of stranded wild and aquarium-housed elasmobranchs. Etiology was largely bacterial or protozoal. Carnobacterium maltaromaticum bacterial meningoencephalitis occurred in salmon sharks (Lamna ditropis), shortfin mako sharks (Isurus oxyrinchus), common thresher sharks (Alopias vulpinus), and one Pacific electric ray (Tetronarce californica). Miamiensis avidus was the most common cause of protozoal meningoencephalitis and found almost exclusively in leopard sharks (Triakis semifasciata) and bat rays (Myliobatis californica) that stranded in San Francisco Bay. Bacterial pathogens were found to use an endolymphatic route of entry, while protozoa entered via the nares and olfactory lamellae. Trauma was the second most common cause of mortality and responsible for 14% (24/168) of wild shark strandings and deaths of aquarium-housed animals.

Evaluation of the effect of protease inhibitors on the viability of Miamiensis avidus using the WST-1 assay

Miamiensis avidus causes scuticociliatosis in cultured olive flounders (Paralichthys olivaceus), leading to economic losses in aquaculture in Korea. Quantitative evaluation of the viability of M. avidus is important to develop an effective vaccine or chemotherapeutic agent against it. We used a colorimetric assay based on the reduction of 2-(4-Iodophenyl)-3-(4-nitrophenyl)-5-(2,4-disulfophenyl)-2H-tetrazolium (WST-1) to quantify the viability of M. avidus. Using this method, we investigated the effect of protease inhibitors on the viability of M. avidus. The assay showed a clear difference in the optical density (OD) of over 10⁴ ciliates, and the metalloprotease inhibitors 1, 10-phenanthroline and ethylenediaminetetraacetic acid (EDTA) reduced the viability of M. avidus by more than 90% when used at concentration of 5 mM and 100 μM, respectively. However, different morphological changes in the parasite were observed when exposed to these two inhibitors. These results indicate that the WST-1 assay is a simple and reliable method to quantify the viability of M. avidus, and metalloproteases are excellent targets for the development of agents and vaccines to control M. avidus infection.

Genome based quantification of Miamiensis avidus in multiple organs of infected olive flounder (Paralichthys olivaceus) by real-time PCR

INTRODUCTION

Miamiensis avidus is the major parasitic pathogen affecting the olive flounder, Paralichthys olivaceus. Recent epidemiological studies have shown that M. avidus infections are becoming increasingly severe and frequent in the olive flounder farming industry.

OBJECTIVES

This study aimed to evaluate the infection density of M. avidus in various organs of the olive flounder including spleen, liver, kidney, stomach, esophagus, intestine, gill, muscle, heart, and brain. Olive flounders were collected from a local fish farm.

METHODS

Each fish was injected subcutaneously with 2.75 × 10³ CFU M. avidus/ fish. Organs infected with M. avidus were obtained after 7 and 25 days. Each organ was examined for parasitic infection using real-time PCR. The primers were designed according to the sequences of 28 s in M. avidus, which was used as a target gene.

RESULTS

Each organ was examined for parasitic infection using real-time PCR. The primers were designed according to the sequences of 28 s in M. avidus, which was used as a target gene. The levels of 28 s rRNA were used to calculate quantitative gene copy number. Real-time PCR of brain (60.58 ± 38.41), heart (64.03 ± 62.40), muscle (6.10 ± 3.12), gill (5.06 ± 4.56), intestine (2.38 ± 1.69), esophagus (4.22 ± 3.72), stomach (3.25 ± 2.68), kidney (0.81 ± 0.15), liver (0.63 ± 0.15), and spleen (11.18 ± 4.08) was performed at 3 days post-infection. At 7 days post-infection, heart (754.15 ± 160.85), brain (247.90 ± 62.91), spleen (38.81 ± 17.52), liver (7.47 ± 4.54), kidney (10.90 ± 3.41), stomach (19.50 ± 8.86), esophagus (39.37 ± 14.10), intestine (17.54 ± 12.63), gill (38.27 ± 20.20), and muscle (33.62 ± 15.07) were measured.

CONCLUSION

The present study, together with previous data, demonstrated that the gill, intestine, and brain are the major target organs of M. avidus in olive flounder. However, this does not mean that tiny amounts of DNA extracted from those tissues of fish during the early stages of infection can guarantee successful detection and/or quantification of M. avidus. Our data suggest that the brain might be the best organ for detection in the early stage.