Presented by: David L. Evans, Ph. D.

1. Spatial Distribution of Benthic Macroinvertebrates in the Pithlachascotee River – Application to Minimum Flows and Levels Presented by: David L. Evans, Ph. D.

2. Acknowledgments • Funded by SWFWMD • Douglas G. Strom • E. Lynn Mosura-Bliss • Laura A. Line • SWFWMD - Michael (Sid) Flannery

3. Background • Florida Statute 372.042 defines MFLs as “the limit at which further withdrawals would be significantly harmful to the water resources or the ecology of the area.” • MFLs vary seasonally and spatially. • Relationships between salinity, flow, and benthic macroinvertebrate community structure.

4. Benthic Invertebrates • Integral in establishing trophic structure of an aquatic ecosystem • Promote exchange of nutrients, oxygen and pollutants between sediments and overlying water • Limited motility - unable to escape environmental conditions • Integrate numerous environmental factors over a relatively long time span

5. Flow and Benthos • Flow can influence biological communities • Food acquisition (filterers), physical adaptation to flow • Influence on residence time, dissolved oxygen, salinity, nutrients and substrate condition • Osmotic tolerances of species

6. Pithlachascotee River Basin

7. Pithlachascotee River Study Area

8. Trend Analysis Plot for Average Flow

9. Historical Salinity Data

10. Top and Bottom Salinity

11. Oyster Distribution

12. Oyster Distribution

13. Oyster Distribution

14. Number of Benthic Invertebrate Taxa

15. Shannon-Wiener Species Diversity Index

16. Benthic Invertebrate Abundance

17. Bray-Curtis Similarity

18. Bray-Curtis Similarity

19. Principal Components AnalysisMean Physicochemical Values

20. Rank Analysis • Dominance Index • Total Abundance • Average Contribution to Dissimilarity

21. Longitudinal distribution of Ampelisca sp.

22. Longitudinal distribution of Mediomastusambiseta

23. Distribution of Hobsoniaflorida

24. Longitudinal distribution of Uromunnareynoldsi

25. Longitudinal distribution of Americorophium sp. A

26. Longitudinal distribution of Polypedilumhalterale

27. Optimal Salinity at Capture

28. Optimal Salinity at Capture (ppt) • Polypedilumhalterale 6 • Americorophium sp. A 7 • Uromunnareynoldsi 8 • Hobsoniaflorida 16 • Apocorophiumlouisianum 18 • Edotiareynoldsi 19 • Grandidieriellabonnieroides 21 From

29. Optimal Salinity at Capture (ppt) • Laeonereisculveri 22 • Ampelisca sp. 30 • Mediomastusambiseta 30 • Fabricinudatrilobata 32

30. Summary • Mean water column salinity 0.5 to 33 • Rapid change between RK 8 and RK 9.5 – Mesohaline zone • Oysters extend to RK 6.6 – 25ppt • 71 taxa at RK 2 to 24 taxa observed between RK 9.5 and RK 10.5

31. Summary • Benthic infauna assemblages at RK 0 through RK 8 significantly differed from assemblages at RK 9.5 through RK 11.2 • Difference was strongly driven by the salinity gradient in mesohaline zone (8-18 ppt) between RK 8 and RK 9.5

32. Potential Indicators • Upper limit mesohaline (8 ppt): • Americorophium sp. A • Uromunnareynoldsi • Polypedilumhalterale • Lower limit mesohaline (18 ppt) • Apocorophiumlouisianum • Edotiatriloba • Laeonereisculveri

33. Minimum Flows and Levels • Extended periods of low flow and increased salinity: • Increase in total number of taxa • Increase in salt-tolerant taxa • Reduction or elimination of oligohaline and freshwater taxa Polypedilumhalterale Uromunnareynoldsi Gammarustigrinus