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Fouling Organisms (fouling + organism)
Selected AbstractsEight polymorphic microsatellite loci markers for the barnacle Balanus amphitrite (syn. Amphibalanus amphitrite) Darwin 1854MOLECULAR ECOLOGY RESOURCES, Issue 1 2009M. A. ROBSON Abstract Balanus amphitrite is a widespread species of barnacle. It is frequently studied, and of great importance to the marine coatings industry due to its significant abundance as a fouling organism on commercial shipping. We isolated and characterized eight highly polymorphic microsatellite loci, to aid in the determination of population genetic structure within this species. All loci showed considerable genetic variation with the number of alleles ranging from two to 14. Expected heterozygosity ranged from 0.74 to 0.98. [source] Phylogenetic relationship and antifouling activity of bacterial epiphytes from the marine alga Ulva lactucaENVIRONMENTAL MICROBIOLOGY, Issue 3 2000Brief report It is widely accepted that bacterial epiphytes can inhibit the colonization of surfaces by common fouling organisms. However, little information is available regarding the diversity and properties of these antifouling bacteria. This study assessed the antifouling traits of five epiphytes of the common green alga, Ulva lactuca. All isolates were capable of preventing the settlement of invertebrate larvae and germination of algal spores. Three of the isolates also inhibited the growth of a variety of bacteria and fungi. Their phylogenetic positions were determined by 16S ribosomal subunit DNA sequencing. All isolates showed a close affiliation with the genus Pseudoalteromonas and, in particular, with the species P. tunicata. Strains of this bacterial species also display a variety of antifouling activities, suggesting that antifouling ability may be an important trait for members of this genus to be highly successful colonizers of animate surfaces and for such species to protect their host against fouling. [source] An initial assessment of native and invasive tunicates in shellfish aquaculture of the North American east coastJOURNAL OF APPLIED ICHTHYOLOGY, Issue 2010M. R. Carman Summary The objective of the study was to assess the distribution of native and invasive tunicates in the fouling community of shellfish aquaculture gear along the U.S. east coast of the Atlantic. Since the 1980s, several species of invasive tunicates have spread throughout the coastal waters of the North American east coast and have become dominant fouling organisms on docks, boat hulls, mooring lines, and in shellfish aquaculture. Invasive and native tunicates negatively impact shellfish aquaculture through increased maintenance costs and reduced shellfish growth. While the presence of alien tunicates has been well documented at piers, harbors, and marinas, there are few published reports of invasive tunicate impacts to aquaculture. We surveyed shellfish aquaculture operations at Martha's Vineyard, Massachusetts and shellfish aquaculturists in other areas along the North American east coast and report high levels of fouling caused by seven invasive, three native, and two cryptogenic species of tunicates. All study sites were fouled by one or more tunicate species. Biofouling control treatments varied among aquaculture sites and were effective in removing tunicates. Invasive and native tunicates should be considered when assessing the economic impacts of fouling organisms to the aquaculture industry. [source] Effects of water flow velocity and fish culture on net biofouling in fish cagesAQUACULTURE RESEARCH, Issue 10 2010John Madin Abstract The effects of water flow, fish feed and cage position on net biofouling was examined in a floating cage fish farm. Fouling of 16 mm mesh net panels suspended inside and outside net cages and exposed to different treatments were monitored weekly until net apertures were completely occluded by the fouling organisms (8 weeks). Results indicate a dramatic reduction in water flow velocity throughout the fish farm due to the cage units themselves and net biofouling. The reduced water flow (<10 cm s,1) inside net cages promoted rapid net biofouling, while rapid water flow outside the net cages (>25 cm s,1) kept the net fouling organisms at bay. Although fish rearing in net cages with inputs of commercial pellet feed increased sessile biofouling (222% higher than outside the net cages) and non-sessile biofouling (570% higher), the type of fish feed used did not significantly affect biofouling development. The study recommends that the geometry of serially arranged net cages, as commonly deployed in tropical tidal estuaries, be reconfigured to improve flow through in order to minimize the impact of fouling. [source] | |||||||||||||