Simulating mechanisms for dispersal, production and stranding of small forage fish in temporary wetland habitats

Movement strategies of small forage fish (<8 cm total length) between temporary and permanent wetland habitats affect their overall population growth and biomass concentrations, i.e., availability to predators. These fish are often the key energy link between primary producers and top predators, such as wading birds, which require high concentrations of stranded fish in accessible depths. Expansion and contraction of seasonal wetlands induce a sequential alternation between rapid biomass growth and concentration, creating the conditions for local stranding of small fish as they move in response to varying water levels. To better understand how landscape topography, hydrology, and fish behavior interact to create high densities of stranded fish, we first simulated population dynamics of small fish, within a dynamic food web, with different traits for movement strategy and growth rate, across an artificial, spatially explicit, heterogeneous, two-dimensional marsh slough landscape, using hydrologic variability as the driver for movement. Model output showed that fish with the highest tendency to invade newly flooded marsh areas built up the largest populations over long time periods with stable hydrologic patterns. A higher probability to become stranded had negative effects on long-term population size, and offset the contribution of that species to stranded biomass. The model was next applied to the topography of a 10 km × 10 km area of Everglades landscape. The details of the topography were highly important in channeling fish movements and creating spatiotemporal patterns of fish movement and stranding. This output provides data that can be compared in the future with observed locations of fish biomass concentrations, or such surrogates as phosphorus ‘hotspots’ in the marsh.

[1]  L. Larsen,et al.  Modeling of hydroecological feedbacks predicts distinct classes of landscape pattern, process, and restoration potential in shallow aquatic ecosystems , 2011 .

[2]  J. Rehage,et al.  Seasonal fish community variation in headwater mangrove creeks in the southwestern everglades: An examination of their role as dry-down refuges , 2007 .

[3]  Donald L. DeAngelis,et al.  Modeling fish dynamics and effects of stress in a hydrologically pulsed ecosystem , 1997 .

[4]  J. Trexler,et al.  Community structure of fishes inhabiting aquatic refuges in a threatened Karst wetland and its implications for ecosystem management , 2004 .

[5]  J. Kushlan Responses of Wading Birds to Seasonally Fluctuating Water Levels: Strategies and Their Limits , 1986 .

[6]  J. Kushlan Effects of a Natural Fish Kill on the Water Quality, Plankton, and Fish Population of a Pond in the Big Cypress Swamp, Florida , 1974 .

[7]  A. Eklund,et al.  LONG-TERM DYNAMICS of an EVERGLADES SMALL-FISH ASSEMBLAGE , 1994 .

[8]  René A. Salinas,et al.  A dynamic landscape model for fish in the Everglades and its application to restoration , 2000 .

[9]  Joel C. Trexler,et al.  Ecological scale and its implications for freshwater fishes in the Florida Everglades , 2001 .

[10]  D. DeAngelis,et al.  Using data from an encounter sampler to model fish dispersal. , 2011, Journal of fish biology.

[11]  E. Marschall,et al.  The cost of dispersal: predation as a function of movement and site familiarity in ruffed grouse , 2004 .

[12]  M. Nungesser,et al.  Reading the landscape: temporal and spatial changes in a patterned peatland , 2011, Wetlands Ecology and Management.

[13]  Donald L. DeAngelis,et al.  A Model for Tropic Interaction , 1975 .

[14]  B. L. Sargeant,et al.  Indirect and direct controls of macroinvertebrates and small fish by abiotic factors and trophic interactions in the Florida Everglades , 2011 .

[15]  J. Kushlan,et al.  ENVIRONMENTAL STABILITY AND FISH COMMUNITY DIVERSITY , 1976 .

[16]  A. Bakun Wasp-waist populations and marine ecosystem dynamics: Navigating the “predator pit” topographies , 2006 .

[17]  J. Trexler,et al.  A Molecular and Stable Isotopic Approach to Investigate Algal and Detrital Energy Pathways in a Freshwater Marsh , 2012, Wetlands.

[18]  C. Richardson,et al.  Subsidy–stress response of macroinvertebrate community biomass to a phosphorus gradient in an oligotrophic wetland ecosystem , 2007, Journal of the North American Benthological Society.

[19]  S. Newman,et al.  Macroinvertebrate community response to eutrophication in an oligotrophic wetland: An in situ mesocosm experiment , 2008, Wetlands.

[20]  Evelyn E. Gaiser,et al.  Periphyton as an indicator of restoration in the Florida Everglades , 2009 .

[21]  M. Kahl Bioenergetics of Growth in Nestling Wood Storks , 1962 .

[22]  Joseph J. Parkos,et al.  Disturbance regime and limits on benefits of refuge use for fishes in a fluctuating hydroscape , 2011 .

[23]  S. Liston Interactions between nutrient availability and hydroperiod shape macroinvertebrate communities in Florida Everglades marshes , 2006, Hydrobiologia.

[24]  Donald L. DeAngelis,et al.  A MODEL FOR TROPHIC INTERACTION , 1975 .

[25]  James W. Porter,et al.  The Everglades, Florida Bay, and coral reefs of the Florida Keys : an ecosystem sourcebook , 2001 .

[26]  J. Trexler,et al.  Assessing the net effect of anthropogenic disturbance on aquatic communities in wetlands: community structure relative to distance from canals , 2006, Hydrobiologia.

[27]  M. Sheaves Nature and consequences of biological connectivity in mangrove systems , 2005 .

[28]  C. Brönmark,et al.  Indirect Effects of Predation in a Freshwater, Benthic Food Chain , 1992 .

[29]  F. Nordlie Patterns of reproduction and development of selected resident teleosts of Florida salt marshes , 2000, Hydrobiologia.

[30]  J. Trexler,et al.  Population dynamics of wetland fishes: spatio-temporal patterns synchronized by hydrological disturbance? , 2005 .

[31]  J. Chick,et al.  Periphyton mat structure mediates trophic interactions in a subtropical marsh , 2008, Wetlands.

[32]  J. Chick,et al.  Targeting Ecosystem Features for Conservation: Standing Crops in the Florida Everglades , 1999 .

[33]  J. Trexler,et al.  Spatiotemporal patterns in community structure of macroinvertebrates inhabiting calcareous periphyton mats , 2005, Journal of the North American Benthological Society.

[34]  M. Allen,et al.  Fish dispersal in a seasonal wetland: influence of anthropogenic structures , 2010 .

[35]  J. Chick,et al.  Spatial scale and abundance patterns of large fish communities in freshwater marshes of the Florida Everglades , 2004, Wetlands.

[36]  D. Gawlik,et al.  The Effects of Water Depth and Emergent Vegetation on Foraging Success and Habitat Selection of Wading Birds in the Everglades , 2011 .

[37]  D. Gawlik THE EFFECTS OF PREY AVAILABILITY ON THE NUMERICAL RESPONSE OF WADING BIRDS , 2002 .

[38]  Holly Gaff,et al.  Evaluation of and insights from ALFISH: a spatially explicit, landscape-level simulation of fish populations in the Everglades , 2004, Hydrobiologia.

[39]  David B. Jepsen,et al.  Effects of seasonality and fish movement on tropical river food webs , 1998 .

[40]  J. Beddington,et al.  Mutual Interference Between Parasites or Predators and its Effect on Searching Efficiency , 1975 .

[41]  J. Trexler,et al.  A preliminary analysis of the correlation of food-web characteristics with hydrology and nutrient gradients in the southern Everglades , 2006, Hydrobiologia.

[42]  L. Harris,et al.  Everglades: The Ecosystem and its Restoration. , 1995 .

[43]  D. DeAngelis,et al.  Modeling seasonal dynamics of small fish cohorts in fluctuating freshwater marsh landscapes , 2010, Landscape Ecology.

[44]  P. Bayley The flood pulse advantage and the restoration of river‐floodplain systems , 1991 .

[45]  P. Mccormick,et al.  Recent and Historic Drivers of Landscape Change in the Everglades Ridge, Slough, and Tree Island Mosaic , 2011 .

[46]  John C. Ogden,et al.  Periphyton in the Everglades: Spatial Variation, Environmental Correlates, and Ecological Implications , 1994 .

[47]  C. Alho,et al.  Biodiversity of the Pantanal: response to seasonal flooding regime and to environmental degradation. , 2008, Brazilian journal of biology = Revista brasleira de biologia.

[48]  M. Daufresne,et al.  Impacts of global changes and extreme hydroclimatic events on macroinvertebrate community structures in the French Rhône River , 2007, Oecologia.

[49]  A. Carpentier,et al.  How do fish exploit temporary waters throughout a flooding episode , 2007 .

[50]  Leonard Pearlstine,et al.  Estimation of water surface elevations for the Everglades, Florida , 2008, Comput. Geosci..

[51]  D. Magoulick,et al.  The role of refugia for fishes during drought: a review and synthesis , 2003 .