Microanatomy of the antennal glands and their Na+/K+-ATPase activity in three true crab species (Brachyura), Portunus pelagicus (Linnaeus, 1758) (Portunidae), Macrophthalmus dentipes Lucas in Guérin, 1836 (Macrophthalmidae) and Eriocheir hepuensis Dai, 1991 (Varunidae)

There are differences between various crab species in the function and structure of organs involved in ionic and osmotic regulation processes. The antennal glands together constitute one of the most important organs involved in the osmoregulation in crabs. The present investigation aimed to study the tissue structure of the antennal glands and their Na+/K+-ATPase (NKA) pump activity in three true crab species from three different habitats, including the marine (Portunus pelagicus (Linnaeus, 1758)), the estuarine (Macrophthalmus dentipes Lucas in Guérin, 1836) and the freshwater habitat (Eriocheir hepuensis Dai, 1991). In this regard, the tissue structure of the antennal glands and the activity of the Na+/K+-ATPase (NKA) pump were assessed in these three selected species. The results showed that the antennal glands in all studied species consisted of two anterior parts and a posterior part. The anterior parts are composed of the proximal tubular region (PT) and the distal tubular region (DT). The PT and DT parts comprised the coelomosac and labyrinths in the anterior portion, and the bladder located in the posterior portion. However, despite the similarity in the general tissue structure of the antennal gland in marine, estuarine and freshwater crab species, some structural differences were observed between those species. Labyrinth cells, coelomosac podocytes, and bladder cells in the estuarine crab M. dentipes contained large vacuoles especially on the top (i.e., near the lumen) of the cells. The highest amount of NKA pump activity was measured in the antennal glands of M. dentipes (). The NKA pump plays a more important role in the estuary and seawater adaptation of crabs, but freshwater species are not highly dependent on the NKA enzyme for osmoregulation.

Artificial infection of the native Korean freshwater prawn Macrobrachium nipponense (De Haan, 1849) (Decapoda, Palaemonidae) with white spot syndrome virus (WSSV)

White spot syndrome virus (WSSV), an important shrimp pathogen that can affect both salt- and freshwater shrimp, has a high mortality rate that can reach up to 100% in 3-10 days. Therefore, we assessed the susceptibility of Macrobrachium nipponense (De Haan, 1849), a freshwater prawn native to Korea, to artificial WSSV infection. Although rearing in water containing WSSV-infected carcasses did not result in infection, M. nipponense was infected with WSSV after being fed a WSSV-containing diet, per os infection, or injection with the purified virus. In the feeding test, the first mortality was observed on the 7th day and cumulative mortality reached 30% by 3 weeks post-infection. After per os infection, experimental animals started dying on the second day and within 3 weeks mortality had reached 90%. In the injection test, the mortality was found to be dose-dependent. Prawn injected with 2.5 × 104, 900 and 80 copies/g body weight exhibited the first mortality at 1, 2 and 4 days post inoculation, with 100, 100 and 50% final mortality at 2, 10 and 12 days post inoculation, respectively. Histological observation revealed inclusion bodies in the gills, antennal glands and other tissues of ectodermal origin. Real-time polymerase chain reaction revealed the increase of viral titers, indicating viral replication in the inoculated host. This forms the first report of the experimental susceptibility of M. nipponense to WSSV.

Refining the Roots of the Beewolf-Streptomyces Symbiosis: Antennal Symbionts in the Rare Genus Philanthinus (Hymenoptera, Crabronidae)

ABSTRACTInsects engage in symbiotic associations with a large diversity of beneficial microorganisms. While the majority of well-studied symbioses have a nutritional basis, several cases are known in which bacteria protect their host from pathogen infestation. Solitary wasps of the generaPhilanthusandTrachypus(beewolves; Hymenoptera, Crabronidae) cultivate the actinomycete “CandidatusStreptomyces philanthi” in specialized antennal gland reservoirs. The symbionts are transferred to the larval cocoon, where they provide protection against pathogenic fungi by producing at least nine different antibiotics. Here we investigated the closest relatives ofPhilanthusandTrachypus, the rare genusPhilanthinus, for the presence of antennal gland reservoirs and symbiotic streptomycetes. Molecular analyses identified “Ca. Streptomyces philanthi” in reservoirs ofPhilanthinus quattuordecimpunctatus. Phylogenies based on the 16S rRNA gene suggest thatP. quattuordecimpunctatusmay have acquired “Ca. Streptomyces philanthi” by horizontal transfer from other beewolf species. In histological sections and three-dimensional reconstructions, the antennal gland reservoirs were found to occupy six antennal segments (as opposed to only five inPhilanthusandTrachypus) and to be structurally less complex than those of the evolutionarily more derived genera of beewolves. The presence of “Ca. Streptomyces philanthi” in antennal glands ofPhilanthinusindicates that the symbiosis between beewolves andStreptomycesbacteria is much older than previously thought. It probably evolved along the branch leading to the monophyletic tribe Philanthini, as it seems to be confined to the generaPhilanthus,Trachypus, andPhilanthinus, which together comprise 172 described species of solitary wasps.