An investigation on the impact of substrate type, temperature, and iodine on moon jellyfish production.

Jellyfish are a popular public aquarium species, however, their collection from natural populations is undesirable due to impact on species abundance and bycatch. Thus, a sustainable supply of jellyfish bred in-house would be highly desirable. Here we describe an investigation into developing a sustainable moon jellyfish, Aurelia aurita, breeding program by determining the impact of substrate type on reattachment of polyps and the influence of iodine and temperature on strobilation and ephyra production. To test whether reattachment and growth of moon jellyfish polyps are influenced by substrate type polyps were provided with anthropogenic and natural substrates after being dislodged in experimental aquaria. Polyps selectively re-attached to plastics rather than natural materials. However, polyp growth was similar on all tested substrates. We tested whether cooling and addition of iodine affected strobilation. A period of cooling of around 10 °C while also introducing soluble iodine to the polyps enhanced strobilation rate. This method produced ephyra at a reliable rate in captivity negating the need for collection of wild individuals providing a supply of individuals for exhibit and for conservation research within a public aquarium. These results demonstrate that plastics should be adopted as an easier to colonize substrate and the use of cooling with iodine addition can enhance sustainable breeding protocols of moon jellyfish and may be relevant to the production of comparable jellyfish species.

Reduction in activity by noxious chemical stimulation is ameliorated by immersion in analgesic drugs in zebrafish.

Research has recently demonstrated that larval zebrafish show similar molecular responses to nociception to those of adults. Our study explored whether unprotected larval zebrafish exhibited altered behaviour after exposure to noxious chemicals and screened a range of analgesic drugs to determine their efficacy to reduce these responses. This approach aimed to validate larval zebrafish as a reliable replacement for adults as well as providing a high-throughput means of analysing behavioural responses. Zebrafish at 5 days post-fertilization were exposed to known noxious stimuli: acetic acid (0.01%, 0.1% and 0.25%) and citric acid (0.1%, 1% and 5%). The behavioural response of each was recorded and analysed using novel tracking software that measures time spent active in 25 larvae at one time. Subsequently, the efficacy of aspirin, lidocaine, morphine and flunixin as analgesics after exposure to 0.1% acetic acid was tested. Larvae exposed to 0.1% and 0.25% acetic acid spent less time active, whereas those exposed to 0.01% acetic acid and 0.1-5% citric acid showed an increase in swimming activity. Administration of 2.5 mg l-1 aspirin, 5 mg l-1 lidocaine and 48 mg l-1 morphine prevented the behavioural changes induced by acetic acid. These results suggest that larvae respond to a noxious challenge in a similar way to adult zebrafish and other vertebrates and that the effect of nociception on activity can be ameliorated by using analgesics. Therefore, adopting larval zebrafish could represent a direct replacement of a protected adult fish with a non-protected form in pain- and nociception-related research.