RESUMO
Epithelial hyperplasia and sloughing of the digestive gland in bivalve mollusks are a global phenomenon and occur in species of commercial interest and cultural significance to indigenous peoples. Where hemocytosis, hyperplasia, and necrosis of digestive tubule cells have been observed associated with electron-dense uncoated virus-like particles (VLPs) 25-45 nm in diameter, the condition has been named digestive epithelial virosis (DEV). This condition has been associated with mortalities of some bivalve species in New Zealand. Similar digestive gland alterations, but without detection of associated VLPs, have been reported in other bivalve species worldwide and are termed "DEV-like" since no virus link has been demonstrated. It remains unclear if DEV is an infectious condition and whether associated VLPs are the cause, a contributor, or simply associated with the observed condition. It is also unclear whether DEV or DEV-like conditions pose a biosecurity or economic threat, or alternatively, whether they reflect a natural cyclic event that does not require disease management. In this mini-review, we summarize the history of digestive epithelial alteration with VLPs (i.e., DEV) or without observation of VLPs (i.e., DEV-like), and we examine the evidence for and against viral-like particles as the cause of DEV in bivalves. We also explore other viral afflictions of bivalves and non-infectious agents, such as harmful algae and xenotoxins, that could elicit similar tissue alterations. Future recommendations for approaches to identify key risk factors that lead to the development of digestive epithelial alterations such as DEV include histological characterization of the digestive gland of marine mollusks; the use of metagenome analysis to design primers that could be used for detection of VLPs and to study host microbiota; disease challenges demonstrating that DEV causes pathology and the relationship between DEV intensity and morbidity/mortality.
Assuntos
Bivalves , Animais , Hiperplasia , Nova ZelândiaRESUMO
We describe the first known blood fluke from a marine mammal, the dugong, Dugong dugon (Sirenia: Dugongidae), which represents a new species of aporocotylid, Cardicola dhangali n. sp. (Digenea: Aporocotylidae). Eggs presumed to be of blood flukes have been previously reported from dugongs. This exciting discovery raises questions regarding evolution and host-switching in the Aporocotylidae, which prior to this study were only known to infect actinopterygian and chondrichthyan fishes. The new species has male and female genital pores opening on the right side of the body, with the male genital pore opening posterior to the entire reproductive system and the testis is extra-caecal. The uterus is highly convoluted, and the ovary is irregularly lobate. These features, together with the size and number of the tegumental spines per row, easily distinguish the new species from the most similar congeners Cardicola aurata Holzer et al., 2008, Cardicola chaetodontis Yamaguti, 1970, Cardicola currani Bullard and Overstreet, 2004, Cardicola forsteri Cribb et al., 2000, C. jiingurru Yong et al., 2016, and Cardicola palmeri Bullard and Overstreet, 2004, all of which infect actinopterygian fishes. Given that Cardicola is the most diverse and least host-specific of the marine aporoctoylid genera, it seems credible that a successful host-switch has occurred from an actinopterygian to D. dugon. Further sampling of sirenians and other marine mammals is warranted to gain a more comprehensive understanding of the evolutionary biology and biodiversity of the blood flukes (superfamily Schistosomatoidea Stiles and Hassall, 1898), but presents a substantial challenge with respect to their conservation status and large size.
RESUMO
Global expansion in fish production and trade of aquatic ornamental species requires advances in aquatic animal health management. Aquatic parasite cultures permit diverse research opportunities to understand parasite-host dynamics and are essential to validate the efficacy of treatments that could reduce infections in captive populations. Monogeneans are important pathogenic parasites of captured captive fishes and exhibit a single-host life cycle, which makes them amenable to in vivo culture. Continuous cultures of oviparous monogenean parasites provide a valuable resource of eggs, oncomiracidia (larvae) and adult parasites for use in varied ecological and applied scientific research. For example, the parasite-host dynamics of Entobdella soleae (van Beneden and Hesse, 1864) and its fish host, Solea solea (Linnaeus, 1758), is one of the most well-documented of all monogeneans following meticulous, dedicated study. Polystoma spp. cultures provide an intriguing model for examining evolution in monogeneans because they exhibit two alternative phenotypes depending on the age of infection of amphibians. Furthermore, assessments of the ecological, pathological and immunological effects of fish parasites in aquaculture have been achieved through cultures of Gyrodactylus von Nordmann, 1832 spp., Benedenia seriolae (Yamaguti, 1934), Neobenedenia Yamaguti, 1963 spp. and Zeuxapta seriolae (Meserve, 1938). This review critically examines methods to establish and maintain in vivo monogenean monocultures on finfish, elasmobranchs and amphibians. Four separate approaches to establish cultures are scrutinised including the collection of live infected hosts, cohabiting recipient hosts with infected stock, cohabiting hosts with parasite eggs or oncomiracidia (larvae) and direct transfer of live adult parasites onto new fish hosts. Specific parasite species' biology and behaviour permits predictive collection of parasite life stages to effectively maintain a continuous culture, while environmental parameters can be altered to manipulate parasite generation time. Parasite virulence and biosecurity are vital components of a well-managed culture to ensure appropriate animal welfare and uncontaminated surrounding environments. Contemporary approaches and techniques are reviewed to ensure optimised monogenean cultures, which ultimately can be used to further our understanding of aquatic parasitology and identify mechanisms to limit infestations in public aquaria, ornamental trade and intensive aquaculture.