Vessel generator noise as a settlement cue for marine biofouling species.

Underwater noise is increasing globally, largely due to increased vessel numbers and international ocean trade. Vessels are also a major vector for translocation of non-indigenous marine species which can have serious implications for biosecurity. The possibility that underwater noise from fishing vessels may promote settlement of biofouling on hulls was investigated for the ascidian Ciona intestinalis. Spatial differences in biofouling appear to be correlated with spatial differences in the intensity and frequency of the noise emitted by the vessel's generator. This correlation was confirmed in laboratory experiments where C. intestinalis larvae showed significantly faster settlement and metamorphosis when exposed to the underwater noise produced by the vessel generator. Larval survival rates were also significantly higher in treatments exposed to vessel generator noise. Enhanced settlement attributable to vessel generator noise may indicate that vessels not only provide a suitable fouling substratum, but vessels running generators may be attracting larvae and enhancing their survival and growth.

Induction of settlement in mussel (Perna canaliculus) larvae by vessel noise.

Underwater sound plays an important role in the settlement behaviour of many coastal organisms. Large steel-hulled vessels are known to be a major source of underwater sound in the marine environment. The possibility that underwater sound from vessels may promote biofouling of hulls through triggering natural larval settlement cues was investigated for the mussel, Perna canaliculus. The mussel larvae showed significantly faster settlement when exposed to the underwater noise produced by a 125-m long steel-hulled passenger and freight ferry. Median time to attachment on the substrata (ie settlement) was reduced by 22% and the time taken for all experimental larvae to settle was reduced by 40% relative to a silent control. There was no difference in the survival of the mussel larvae among the various noise treatments. The decrease in settlement time of the mussel larvae appeared to correlate with the intensity of the vessel sound, suggesting that underwater sound emanating from vessels may be an important factor in exacerbating hull fouling by mussels.

Development of a novel technique for axenic isolation and culture of thraustochytrids from New Zealand marine environments.

AIMS: To maintain axenic cultures of commercially important thraustochytrids, a novel procedure was developed for the isolation of zoospores and sporangium from heterotrophic seawater samples and axenic culture on solid media. METHODS AND RESULTS: Thraustochytrid cultures were isolated from Whangapoua Harbour in North East New Zealand and subjected to two antibiotic and antifungal treatment regimes designed to eliminate bacteria and fungi. Antibiotic trial 1 was designed to determine the appropriate combination of antibiotics (including streptomycin/penicillin, ampicillin, rifampicin, nalidixic acid, tetracycline, gentamicin and the antifungal agent nystatin). Antibiotic trial 2 determined the optimal dosing frequency and concentration of the antibiotics, and antifungal found to be the most promising in trial 1. Axenic cultures were then spread plated onto nutrient agar containing the optimal antibiotic cocktail, and pure thraustochytrid colonies were purified on solid media using standard microbiological techniques. CONCLUSIONS: Removal of bacteria and fungi was best accomplished using a mixture of three antibiotics and one antifungal; rifampicin (300 mg l(-1)), streptomycin/penicillin (25 mg l(-1)) and nystatin (10 mg l(-1)) were incorporated in seawater samples and incorporated into cultures every 24 h for a minimum of 2 days. SIGNIFICANCE AND IMPACT OF THE STUDY: The axenic isolation and culture of marine thraustochytrids from a marine habitat in New Zealand have significant implications for the biotechnological development of these potentially valuable protists. This method has global significance as it is reasonable to assume it could be used throughout the world to obtain axenic thraustochytrid cultures.