| Contributors | Affiliation | Role |
|---|---|---|
| Campbell, Justin | Smithsonian Institution (NMNH) | Principal Investigator |
| Newman, Sawyer | Woods Hole Oceanographic Institution (WHOI BCO-DMO) | BCO-DMO Data Manager |
Sampling details
50 small seagrass plots (0.25m2, all comprised of one species, Thalassia testudinum) were established at 13 shallow sites in the Western Atlantic. Each plot was assigned to one of ten treatments comprising a factorial manipulation of caging, nutrient supply, and canopy clipping: (1) control (2) partial cage (3) full cage (4) added nutrients (5) added nutrients + partial cage (6) added nutrients + full cage (7) full cage + half canopy clip (8) full cage + full canopy clip (9) full cage + added nutrients + half canopy clip (10) full cage + added nutrients + full canopy clip. Seagrass shoot density was measured at two time periods (once at the end of summer 2018 and again at the end of winter 2019). During each sampling shoot density was measured twice at haphazard (non-overlapping) locations within each plot from replicate 15cm PVC rings. The dataset displays the total sum of shoot counts.
Site location details
ANDR: Andros, Bahamas (24°53'54.3" N, 77°54'25.2" W)
BERM: Bailey's Bay, Bermuda (32°15'49.9" N, 64°49'50.5" W)
BOCA: Bocas Del Toro, Panama (9°21'05.8" N, 82°15'27.8" W)
BONA: Lac Bay, Bonaire (12°06'44.3" N, 68°13'42.0" W)
CARR: Carrie Bow Cay, Belize (16°49'24.8" N, 88°06'16.2" W)
CAYM: Little Cayman, Cayman Islands (19°40'14.6" N, 80°03'21.3" W)
CORP: Corpus Christi, TX (27°55'47.9" N, 97°02'05.2" W)
CRYS: Crystal River, FL (28°42'50.4" N, 82°49'08.4" W)
ELEU: Eleuthera, Bahamas (25°27'53.5" N, 76°37'35.8" W)
GALV: Galveston, TX (29°02'41.8" N, 95°10'15.7" W)
JOES: St. Joe's Bay, FL (29°42'05.0" N, 85°19'34.6" W)
NAPL: Naples, FL (26°29'48.6" N, 82°09'40.0" W)
PUER: Puerto Morelos, Mexico (20°52'04.5" N, 86°51'35.4" W)
- Removed units from column headers
- Replaced spaces in column header names and replaced them with underscores ("_")
- Converted latitude and longitude values from degrees, minutes, seconds to decimal degrees
- Rounded latitude and longitude fields to 6 degrees of precision
- Rounded absolute_leaf_productivity field to 9 degrees of precision
| Parameter | Description | Units |
| site | Site name or location | unitless |
| latitude | Site latitude in decimal degrees; a positive value indicates a Northern coordinate | decimal degrees |
| longitude | Site longitude in decimal degrees; a negative value indicates a Western coordinate | decimal degrees |
| season | Season sample collection took place | unitless |
| plot | Plot ID number | unitless |
| clipping | Level of seagrass clipping; no = no clipping, partial = half canopy removed, full = full canopy removed | unitless |
| nutrients | Level of nutrients; ambient = no added nutrients; enriched = added nutrients | unitless |
| cage | Level of cage; no = no cage, partial = partial 4-sided cage, full = full cage | unitless |
| absolute_leaf_productivity | Grams of new leaf material produced per shoot per day | grams |
NSF Award Abstract:
The warming of temperate marine communities is becoming a global phenomenon, producing new biotic interactions that can result in a series of cascading effects on ecosystem structure. For example, the poleward expansion of herbivore populations can lead to the consumption of habitat-forming vegetation, which alters the ecological services provided by coastal environments (a phenomenon known as tropicalization). Many of the habitats at risk, such as kelp forest and seagrass beds, provide foundational habitat that supports complex food webs. Seagrass meadows along the Gulf of Mexico are currently experiencing an influx of tropical grazers, however a integrated understanding of how these communities might ultimately respond is lacking. This project describes the first experiment to quantify the disruptive effect of tropicalization on the ecology of a widely-distributed seagrass. A major contribution of this project will be the development of a seagrass research collaborative network to serve as a platform for broader scientific inquiry and future collaboration. The collaboration spans a total of 11 institutions, and this network will foster extensive collaborations among junior and senior scientists, as well as many undergraduate and graduate students. Given the geographic scope of this work, the research team will further pursue outreach opportunities across the network by hosting a series of public lectures and science café events promoting topics in marine ecology and conservation.
This study will develop a large-scale manipulative experiment across the Caribbean, premised upon a comparative network of 15 marine sites, which will quantify how temperature and light interact with grazer effects on the dominant tropical seagrass, Thalassia testudinum. Sites have been selected along a latitudinal gradient (from Bermuda to Panama), such that light and temperature vary, allowing the investigators to test for the effects of abiotic factors on the ecological effects of increased grazing (tropicalization simulated via artificial leaf clipping). At each of the 15 marine sites, grazing treatments will be crossed with nutrient manipulations in a factorial design for 18 weeks, after which seagrass structure and functioning will be assessed via measurements of areal productivity, shoot density, aboveground biomass, and carbohydrate storage. Experiments will be conducted both in the summer and winter seasons, when abiotic gradients are at their weakest and strongest, respectively. Emerging statistical techniques in hierarchical mixed modeling and structural equation modeling will further allow for integration of experimental and observational data.
| Funding Source | Award |
|---|---|
| NSF Division of Ocean Sciences (NSF OCE) |