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CESN Main PageCoastal & Estuarine Science News (CESN)Coastal & Estuarine Science News (CESN) is an electronic publication providing brief summaries of select articles from the journal Estuaries & Coasts that emphasize management applications of scientific findings. It is a free electronic newsletter delivered to subscribers on a bimonthly basis. June 2006ContentsAn Estuarine Paradox: Introduced Alga Dominates, but Supports Diversity Too An Estuarine Paradox: Introduced Alga Dominates, but Supports Diversity TooGracilaria vermiculophylla, a filamentous macroalga native to the western Pacific, looks so much like its Atlantic native Gracilaria sister species that its invasion of Atlantic waters went largely undetected until molecular techniques revealed it was in fact a different species. It doesn’t go unnoticed any more: a recent study of macroalgal abundance and distribution in Hog Island Bay, VA, found that Gracilaria vermiculophylla was by far the most abundant macroalgae species in all seasons and in all locations and elevations sampled, comprising 74% of the total algal biomass. Interestingly, Gracilaria abundance was also correlated with species richness and abundance of other filamentous algae species, which were often attached to or entangled with the invader. Along transects from the mainland across the lagoon to an offshore barrier island, the highest macroalgal diversity and biomass was observed in mid-lagoon. While similar patterns in other studies often have been attributed to nutrient gradients, these authors believe that abundant mid-lagoon shell substrate conducive to algal attachment is partly responsible for the patterns observed here. Common Reed Too Common for Mummichogs: Invader Provides Poor HabitatWhile many studies have documented various (mostly negative) impacts of the widespread invasive plant Phragmites australis (common reed) in the eastern U.S., until recently none had examined marsh habitat quality as a function of stage of Phragmites invasion. Characterizing marsh sites over a large geographic area (study sites were in New Jersey, Delaware, and Maryland) as “natural marsh,” “initial invasion,” “early invasion,” and “late invasion,” researchers recently compared the marshes’ physical characteristics, hydrology, and use by a resident marsh fish, the mummichog Fundulus heteroclitus. Consistent with what other studies have found, biomass and plant height increased with increasing invasion stage, while stem density declined. Increasing amounts of Phragmites were associated with drier marsh conditions: decreased flooding frequency, water depth, and percent of marsh covered with standing water. As stage of invasion increased, the abundance of mummichog decreased, likely due to drier conditions at the more highly invaded sites. This pattern was observed in all marshes, but the effect was less prominent in Delaware. A rarer species, Fundulus luciae, was also less abundant where Phragmites was more abundant. Do These Oysters Need Salt? Landings and Salinity in the Gulf of MexicoMore than half of the U.S. oyster harvest comes from the Gulf of Mexico, so it makes sense that steps should be considered to protect or enhance this valuable fishery and to evaluate the potential impacts of management actions on oyster yields carefully. Because oyster yields are highest at intermediate salinities (in the middle of their range of 10 – 30 ppt), managers occasionally consider projects to improve Gulf oyster landings by reducing saltwater intrusion, thereby decreasing salinities to this optimal range. These plans would theoretically work if the oysters in question live at the high end of their salinity range, but if they’re at the low end of the range more freshwater would only decrease yields. An analysis of more than 50 years of oyster landings and freshwater discharge data in five Gulf states revealed that oyster landings were at their lowest when nearby river discharges increased, and conversely, landings went up when discharge was down. DOM Dynamics in DenmarkAs recent research has shown, just because organic matter in aquatic systems is in the dissolved phase does not mean it is inert. In fact, because dissolved organic matter (DOM) is the largest reservoir for organic carbon in the aquatic environment, it may feed the processes that lead to eutrophication by absorbing light, fueling bacterial respiration, and carrying large quantities of carbon, nitrogen, and phosphorous to estuaries and coastal waters. For these reasons, a better understanding of DOM dynamics is important. In one Danish estuary, land use was found to have significant impacts on the quality and quantity of DOM loadings. Forested subbasins of the watershed contributed substantial DOM throughout the year, but especially during the rainy season. Subbasins characterized by agricultural land use contributed a smaller, more constant flow of DOM to the estuary throughout the year. While forested lands provide more DOM than those used for agriculture, the nutrients bound in this material may be less bioavailable than those from agricultural lands. Results of the study suggest that reducing the agricultural area of the watershed to about 50% of the watershed’s total area could lead to a substantial decrease in eutrophication risk to the estuary and adjacent coastal waters. |