An analytical method of predicting Lee-Kesler interaction parameters
Karen Kesler , Vincent Politano , Kennedy Paynter
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Karen Kesler, Vincent Politano, Kennedy Paynter Differentiating the impact of the physical and biotic components of the eastern oyster, Crassostea virginica, on the benthic reef community
description
Differentiating the impact of the physical and biotic components of the eastern oyster, Crassostea virginica , on the benthic reef community . Karen Kesler , Vincent Politano , Kennedy Paynter. The physical and biotic contributions of Crassostrea virginica. Physical Structure: - PowerPoint PPT Presentation
Transcript of Karen Kesler , Vincent Politano , Kennedy Paynter
Karen Kesler, Vincent Politano, Kennedy Paynter
Differentiating the impact of the physical and biotic components of the eastern oyster,
Crassostea virginica, on the benthic reef community
The physical and biotic contributions of Crassostrea virginica
• Physical Structure:• Hard surface for settlement• Complex arrangement of oyster shells (Luckenbach et al. 2005)
• Complexity correlated with higher biomass, abundance, and species richness (Cranfield et al 2004, Coen et al. 2007)
• Reduces turbidity (Meyer and Townsend 2000)
•Biotic Input:• Benthic-pelagic couplers• Biodeposit production
Past Research
• Tolley and Volety 2005: C. virginica • No overall difference between live and shell treatments• Some species level differences
• Silver Botts et al. 1996: Dreissena spp • no differences in amphipods, turbellarians, and
hydrozoans abundances• Chironomid abundance higher on live mussels
• Stewart et al. 1998: Dreissena spp • macroinvertebrate biomass higher on live mussels
Question and Hypotheses
• Is the Crassostrea virginica reef community predominantly responding to the presence of the oyster structure or is there an additional response to the biotic component of a live oyster?
• Ho: The two treatments will have equal abundance and biomass. • May indicate structure as the dominating influence
• HA: The live oyster treatment will have higher abundance and/or biomass. • May indicate an additional benefit of live oyster
Methods
• In July 2009, eighty C. virginica clumps were collected from the Chester River, MD
• Clumps were cleaned of all epibiotics
• Half of the clumps were shucked and glued shut to reassemble the structure of a live oyster
• 4 clumps were zip tied to a 57.8 cm2 tray
• 10 trays of live oysters and 10 trays of oyster shell of equal complexity were deployed into the Patuxent River, MD
• Trays were placed 3 m apart in a 12 m by 15 m grid
Methods • In October 2009 three trays of each treatment were
removed for a mid-experiment evaluation
• Oysters and epifauna were preserved in ethanol • Epifauna were cleaned from the oysters, identified,
enumerated, and biomassed• ANOVA with an adjusted alpha was performed
Results: Least Abundant Taxa
0100200300400500600700800900
1000 LiveOyster Shell
Taxa
Abu
ndan
ce p
er tr
ay
Results: Most Abundant Taxa
polychaeta amphipoda platyhelminthes copepoda0
5000
10000
15000
20000
25000
30000LiveOyster Shell
Taxa
Abu
ndan
ce p
er tr
ay
Results: Taxa with Lowest Biomass
cirrip
edia
bivalv
ia
polyc
haeta
amphip
oda
actini
aria
platyh
elmin.
..misc
.
gastr
opoda
cope
poda
xanth
oidea
isopod
a
shrim
p0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8Live Oyster Shell
Taxa
Dry
bio
mas
s per
tray
(g)
Results: Taxa with Highest Biomass
teleostei tunicata0
1
2
3
4
5
6LiveOyster Shell
Taxa
Dry
bio
mas
s per
tray
(g)
Discussion
• No difference in reef community biomass or abundance• Structure may have been a stronger influence on
community development than the biotic component • Tidal movement and wave action may have influenced
results
What’s Next ?
• Remaining 14 trays moved to deeper water in November 2009• Reduced influence of tidal and wave action
• Removed in July 2010• Currently processing trays• New data will present a more refined data set
Acknowledgements
• Paynter Lab staff and students• Kyle Rambo: Naval Air Station, Patuxent River• Oyster Recovery Partnership (ORP)• National Oceanic and Atmospheric Administration –
Chesapeake Bay Office (NCBO)• Army Corps of Engineers, Baltimore District
References
• Coen, LD, RD Brumbaugh, D Bushek, R Grizzel, MW Luckenbach, MH Posey, SP Powers, and SG Tolley. 2007. Ecosystem services related to oyster restoration. Marine Ecology Progress Series 341: 303-307.
• Cranfield, HJ, AA Rowden, DJ Smith, DP Gordon, and KP Michael. 2004. Macrofaunal assemblages of benthic habitat of different complexity and the proposition of a model of biogenic reef habitat regeneration in Foveaux Strait, New Zealand. Journal of Sea Research 52: 109- 125.
• Luckenbach, MW, LD Coen, PG Ross, Jr. and JA Stephen. 2005. Oyster reef habitat restoration: relationships between oyster abundance and community development based on two studies in Virginia and South Carolina. Journal of Coastal Research 40: 64-78.
• Meyer, DL, and EC Townsend. 2000. Faunal utilization of created intertidal eastern oyster (Crassostrea virginica) reefs in the southeastern United States. Estuaries 23(1): 34-45.
• Silver Botts,P, BA Patterson and DW Schloesser. 1996. Zebra mussel effects on benthic invertebrates: physical or biotic? Journal of the North American Benthological Society 15(2): 179-184.
• Stewart, TW, JG Miner, and RL Lowe. 1998. Quantifying mechanisms for zebra mussel effects on benthic macroinvertebrates: organic matter production and shell-generated habitat. Journal of the North American Benthological Society 17(1): 81-94.
• Tolley, SG and AK Volety. 2005. The role of oysters in habitat use of oyster reefs by resident fishes and decapod crustaceans. Journal of Shellfish Research 24(4): 1007-1012.
Questions?
