Project: Cascading effects of an invasive seaweed on estuarine food webs of the southeastern US

Acronym/Short Name:Gracilaria effects
Project Duration:2011-08 - 2016-07
Geolocation:Georgia and South Carolina coasts

Description

Description from NSF award abstract:
During the last decade, the Asian seaweed, Gracilaria vermiculophylla, has proliferated along high-salinity mudflats in several Georgia and South Carolina estuaries. The invasion is noteworthy because the mudflats in these estuaries were historically devoid of macrophyte-based primary production and structure. Gracilaria has few native analogues in these mudflat environments, and thus represents an opportunity to examine the ecosystem consequences of an invasion within an historically-unexploited niche. In theory, Gracilaria affects populations of species that are directly dependent on the invader for structure and food, as well as altering community- and ecosystem-level processes such as detrital production and food web structure. Through a combination of manipulative field experiments, laboratory assays and stable isotope analysis, the investigators will test three mechanisms by which Gracilaria influences native community structure. The novel structure and primary production generated by Gracilaria vermiculophylla may be 1) increasing rates of secondary production, 2) increasing levels of mudflat microbial production through leeching of dissolved nutrients, and 3) increasing detrital input to microbial and macrobial food webs.

This project will provide a mechanistic understanding of the multiple cascading impacts of an invasive species within the estuarine community. Species invasions that alter ecosystem functions are usually the most profound. These alterations are often generated by a small number of invaders that create physical structure, including important biogenic habitat, de novo. By altering physical structure, these non-native ecosystem engineers alter local abiotic conditions, interactions between species, and species composition. Highly influential invaders may also change food web structure and trophic flow of energy and materials. Such substantive food web changes can occur when an influential invader provides nutrients or resources that are different in quality, quantity or both. An invasive species that both provisions new physical structure and fundamentally alters food web structure could exert an overwhelming influence on native communities when these mechanisms act in synergy.


DatasetLatest Version DateCurrent State
Experimental results on the response of Diopatra final size to Gracilaria abundance after four weeks in 2013 (Gracilaria effects project)2016-04-07Final no updates expected
Experimental results on the response of Diopatra size to Gracilaria-mediated resource items in 2013 (Gracilaria effects project)2016-04-07Final no updates expected
Abundance of Gracilaria and Diopatra along a tidal mudflat in Charleston Harbor, South Carolina in 2013 (Gracilaria effects project)2016-04-07Final no updates expected
Results of stable isotope analysis (C, N) of the posteriorly regenerated muscle tissue of Diopatra from the Georgia and South Carolina coasts in 2013 (Gracilaria effects project)2016-04-07Final no updates expected
Relative growth rate of Gracilaria in Charleston Harbor, South Carolina in 2013 (Gracilaria effects project)2016-04-07Final no updates expected
Response of Diopatra final size to Gracilaria abundance and the predator-exclusion cages in Fort Johnson, Charleston South Carolina from 2012 (Gracilaria effects project)2016-04-07Final no updates expected
Relative growth rate of Gracilaria with depth below the water surface in Charleston Harbor, South Carolina in 2013 (Gracilaria effects project)2016-04-07Final no updates expected
Accession numbers and characteristics of 33 microsatellite loci developed for Gracilaria vermiculophylla2015-12-22Final no updates expected
The genotypes from 9 microsatellites generated on individuals of the red invasive seaweed Gracilaria vermiculophylla2015-12-18Final no updates expected

People

Principal Investigator: James E. Byers
University of Georgia (UGA)

Principal Investigator: Erik Sotka
Grice Marine Laboratory - College of Charleston (GML-CoC)

Contact: James E. Byers
University of Georgia (UGA)