Experiments to examine transplant procedures on the seagrass Halodule beaudettei

Land, Frederick Joseph

17 September 2007

During the growing seasons of 1999 and 2000 five experiments were performed to test growth of the seagrass Halodule beaudettei (shoal-grass) in nursery pond conditions. Sediment oxidation state, sediment source, container type, flow regime, and light transmittance were tested to improve nursery pond cultivation techniques and to test assumptions about the decline of seagrasses in Galveston Bay, Texas. Oxidized and reduced sediments exhibited no statistical difference as mean percent change in the number of stems of shoal-grass, after 47 days. Sediment from three source locations, West Bay, East Beach Lagoons, and the experimental pond bottoms, showed no significant difference in the mean percent change in the number of stems of shoal-grass at 48 and 95 days. A statistical difference was seen in the container type experiment, trays versus pots, at 48 days where shoal-grass had double the number of stems produced in trays; however no significant difference was found at 93 days. A significant difference was found in the flow regime experiment, no-flow versus flow, at 47 days in the mean percent change of shoal-grass with double the number of stems produced in the flow regime. Significant differences were observed between the low light and high light treatments with shoal-grass, widgeongrass (Ruppia maritima), star grass (Halophila engelmannii), and turtlegrass (Thalassia testudinum), with survival and growth occurring in the high light treatment and decline and death occurring in the low light treatment. The importance of reduced sediment may have been overstated in the past as sediment reduction occurs rapidly with submersion. It appears that while West Bay sediment did not have a deleterious effect on shoal-grass, West Bay simulated light conditions did. Container type seems to be important at first but not so much in the long term. Some flow, water movement, or current appears to be important.

Halodule

Seagrass

shoal-grass

Nursery

Ruppia

Thalassia

Halophila

Oxidation

flow

light

sediment

Examining Wrack in Mosquito Lagoon to Analyze Biodiversity And Seagrass Viability

Jerrell, Nicole

01 January 2024

Seagrass restoration of Halodule wrightii, has become crucial as seagrass coverage in the Indian River Lagoon (IRL) declined by 58% between 2011 and 2019. To understand the abundance of seagrass fragments available for natural recruitment and restoration, we tracked the abundance of viable fragments found in the wrack in Mosquito Lagoon. Wrack is plant material, including seagrass fragments, mangrove propagules, and detritus. Seagrass fragments were considered viable if the fragment had an apical meristem present. Replicate samples were collected from 5 locations every two weeks, starting in September 2022 and ending in September 2023, and the samples were processed in the laboratory. To date, H. wrightii is the most common species and is most abundant during the fall season. Among the total H. wrightii fragments collected, 54.1% had apical meristems, the growth tips needed to produce leaf-bearing shoots. Annually, on average, 7 fragments with apical meristems per square meter a month were recorded. Among only fragments with an apical meristem found during this study, 92.8% had less than five shoots. The average fragment that was washing ashore had only two shoots. This study will assist restoration practitioners in understanding the availability of viable H. wrightii fragments for natural and active restoration efforts.

Halodule wrightii

Restoration

Submerged Aquatic Vegetation

Clonal Reproduction

Marine Biology

Terrestrial and Aquatic Ecology

Heavy Metal Accumulation in Seagrasses in Southeastern Florida

Smith, Erin

11 June 2018

Seagrass beds are among the most ecologically important systems in the marine environment. They provide the primary production to nearby coral reef and mangrove communities, and seagrasses comprise a large component of the diets of many marine organisms including fishes, small invertebrate species, and many protected species such as manatees and sea turtles. This consumption provides a pathway for many contaminants to enter the marine food web via the seagrasses. The coastal location of seagrass beds causes them to be especially susceptible to anthropogenic pollution, including accumulation of heavy metals, which has been shown to have many adverse health effects in the seagrasses and marine organisms that feed on them. This study assessed the heavy metal concentrations of seagrasses in three regional locations in South Florida: Port of Miami, Card Sound Aquatic Preserve, and Florida Bay. Three species of seagrasses, Thalassia testudinum, Halodule wrightii, and Syringodium filiforme, which comprise the majority of South Florida seagrass beds, were collected monthly for a period of one year and analyzed for ten heavy metals: (arsenic (As), cadmium (Cd), copper (Cu), iron (Fe), mercury (Hg), manganese (Mn), nickel (Ni), lead (Pb), selenium (Se), zinc (Zn)). Concentrations were compared across locations, season, species, and plant part (leaves, shoots, roots, and rhizomes). Concentration ranges, in µg/g (ppm), found in seagrass tissues for all included locations, species, and plant parts were: As (0.02-2.95), Cd (0.09-10.72), Cu (0.38-33.68), Fe (1.52-1877.43), Pb (0.78-156.20), Mn (0.79-300.15), Hg (0.03-16.46), Ni (0.67-87.74), Se (0.01-4.79), Zn (1.48-669.44). Statistical analysis showed significant difference in concentrations among locations, season, species, and plant morphology.

Seagrass; Heavy Metals; Florida

Thalassia testudinum

Halodule wrightii

Syringodium filiforme

Environmental Chemistry

Marine Biology

Environmental Change and Molluscan Death Assemblages: An Assessment of Ecological History Along a Carbonate Bank in Florida Bay

Ferguson, Chad Allen

06 November 2009

No description available.

Biology

Earth

Ecology

Environmental Science

Geology

Paleoecology

Paleontology

molluscan death assemblages

subfossil

carbonate bank

body size

sea shell

mollusk

coastal monitoring

seagrass bed

environmental change

anthropogenic

nutrient enrichment

coastal environment

Thalassia

Halodule

Cerithium

Florida Bay