#PAGE_PARAMS# #ADS_HEAD_SCRIPTS# #MICRODATA#

Plant-mediated community structure of spring-fed, coastal rivers


Authors: Matthew V. Lauretta aff001;  William E. Pine, III aff002;  Carl J. Walters aff003;  Thomas K. Frazer aff004
Authors place of work: National Oceanic Atmospheric Administration, National Marine Fisheries Service, Miami, FL, United States of America aff001;  Department of Wildlife Ecology and Conservation, University of Florida, Gainesville, FL, United States of America aff002;  Fisheries Research Centre, University of British Columbia, Vancouver, British Columbia, Canada aff003;  School of Natural Resources and Environment, University of Florida, Gainesville, FL, United States of America aff004
Published in the journal: PLoS ONE 14(12)
Category: Research Article
doi: https://doi.org/10.1371/journal.pone.0219236

Summary

Quantifying ecosystem-level processes that drive community structure and function is key to the development of effective environmental restoration and management programs. To assess the effects of large-scale aquatic vegetation loss on fish and invertebrate communities in Florida estuaries, we quantified and compared the food webs of two adjacent spring-fed rivers that flow into the Gulf of Mexico. We constructed a food web model using field-based estimates of community absolute biomass and trophic interactions of a highly productive vegetated river, and modeled long-term simulations of vascular plant decline coupled with seasonal production of filamentous macroalgae. We then compared ecosystem model predictions to observed community structure of the second river that has undergone extensive vegetative habitat loss, including extirpation of several vascular plant species. Alternative models incorporating bottom-up regulation (decreased primary production resulting from plant loss) versus coupled top-down effects (compensatory predator search efficiency) were ranked by total absolute error of model predictions compared to the empirical community observations. Our best model for predicting community responses to vascular plant loss incorporated coupled effects of decreased primary production (bottom-up), increased prey search efficiency of large-bodied fishes at low vascular plant density (top-down), and decreased prey search efficiency of small-bodied fishes with increased biomass of filamentous macroalgae (bottom-up). The results of this study indicate that the loss of vascular plants from the coastal river ecosystem may alter the food web structure and result in a net decline in the biomass of fishes. These results are highly relevant to ongoing landscape-level restoration programs intended to improve aesthetics and ecosystem function of coastal spring-fed rivers by highlighting how the structure of these communities can be regulated both by resource availability and consumption. Restoration programs will need to acknowledge and incorporate both to be successful.

Keywords:

Invertebrates – Predation – Biomass – Marine fish – Rivers – Vascular plants – Freshwater fish – Food web structure

Introduction

Human alterations of the landscape and associated changes in the physical and chemical properties of aquatic environments have resulted in the loss of submersed vascular plants from shallow aquatic ecosystems around the world [1, 2, 3]. For example, in nutrient-enriched systems, algae capable of rapid nutrient uptake and growth can dominate and potentially exclude vascular plants with lower nutrient uptake, assimilation, and growth rates [4]. Because plants play a central role in the ecology of aquatic ecosystems in a variety of ways, including contributing to ecosystem production, modifying biogeochemical processes, and mediating biotic interactions [1, 5, 6, 7], changes in aquatic plant communities may have profound consequences on ecosystem structure. Rooted vascular plants link benthic substrates to the overlying water column through the uptake of nutrients from sediment pore waters and transport of organic matter, minerals, and gases to both the water and benthic environments [8, 9]. The above-ground structure provided by these plants also decreases sediment erosion and resuspension by reducing water velocity and turbulence at the water-sediment interface [8, 10, 11]. As a consequence, water clarity and light availability are increased and a positive feedback loop for vascular plant primary production is provided.

Plants directly support the production of higher trophic levels and have been shown to have a major influence on the abundance and diversity of stream faunal communities [12]. Plants mediate predator-prey interactions between fishes and invertebrates by providing refuge habitat for prey populations and decreasing prey encounter rates of predators [13], allowing predator and prey populations to coexist at relatively high densities compared to unstructured habitats [14, 15, 16]. The effects of vascular plant loss and replacement by algal species on the faunal communities that they support are not currently well-understood [17], but this replacement is observed globally and is increasingly of concern to water resource users and managers [2, 3, 18, 19].

Due to their unique hydrogeological and biological properties, Florida’s spring-fed rivers are excellent model ecosystems to study the effects of vegetative habitat loss on community structure. These rivers generally have stable streamflow and water temperatures, as well as extremely high rates of primary production [7, 20] that support diverse communities of plants, invertebrates, and fishes [21, 22]. Spring systems are also currently of significant conservation concern because of increased demands on groundwater for consumptive uses, which can lead to reduced spring discharge [23, 24], salinization [23], altered nutrient dynamics [25], and changes in floral and faunal communities [18, 26]. Within these spring ecosystems, documented shifts in the composition and biomass of primary producers are temporally concordant with changes in watershed land-use, including increased agricultural and residential development, and associated changes in streamflow and water quality [25, 27]. Of particular concern is the rapid decline of once dominant vascular plants, including Vallisneria americana, Potamogeton spp., and Sagittaria kurziana in several systems, and the widespread proliferation of filamentous macroalgae, including Chaetomorpha spp., Gracilaria spp., and Lyngbya spp. [27, 28, 29], which may have effects on higher trophic levels [17].

The causal mechanisms of vascular plant loss from the rivers or the effects on faunal communities within these systems are not fully understood [18]. However, resource managers are tasked with developing restoration and management plans for these systems, creating a need for new science to inform restoration strategies. As an example, the loss of vascular plants, which provide forage and refuge habitat, may alter invertebrate grazer communities, predator-prey dynamics of fishes, and other important population-level interactions. Such alterations may lead to undesirable shifts in fish and invertebrate communities and loss of ecosystem function, which is of critical importance to managers and resource users concerned with the conservation of these unique coastal ecosystems [30, 31, 32].

To evaluate fish and invertebrate community responses to vegetative habitat loss, we (1) conducted a large-scale field assessment of ecosystem structure and function in two adjacent spring-fed rivers (Chassahowitzka and Homosassa rivers) where changes in vascular plant biomass (and replacement by filamentous macroalgae) have occurred with different trajectories; (2) used this information to construct a food web model using empirical estimates of plant, invertebrate, and fish absolute biomass and trophic interactions from the more vegetated river (Chassahowitzka River); (3) simulated seasonal filamentous macroalgae blooms and vascular plant decline over long time periods to quantify the corresponding responses in fishes and invertebrates under alternative scenarios of primary producer biomass with coupled predator-prey dynamics (i.e., high algae or plant biomass resulting in low predator search efficiency and vice-versa); and, (4) evaluated the absolute error in predicted community structure by comparing model projections with the observed plant, invertebrate and fish absolute biomass and trophic dynamics from the adjacent river where native vascular plants have been largely extirpated and replaced by filamentous macroalgae (Homosassa River). Our fundamental questions are: “What are the overall effects of primary producer composition and biomass change on fish and invertebrate community structure in spring-fed, coastal rivers?” and “Which predator-prey trophic dynamics–specifically prey availability and predator search efficiency under high or low levels of either vascular plants or filamentous macroalgae–best explain the observed differences in community structure?” Our overall goal was to capture the predominant trophic dynamics between plants, invertebrates, and fishes that were best reflected in the community structures observed in the two river systems, and to develop an ecosystem model incorporating mechanistic dynamics that account for these observed patterns to guide restoration strategy evaluation.

Materials and methods

Study systems

The Chassahowitzka and Homosassa rivers are located along the west coast of peninsular Florida, north of Tampa Bay. Both rivers originate as large artesian springs with mean discharge >2.49 m3/s [33] and flow west directly into the Gulf of Mexico. Riparian zones differ between the two rivers; the Homosassa River has extensive residential development whereas the Chassahowitzka River is primarily within the confines of state and federal protected lands with residential development restricted to areas outside of park boundaries and primarily along canals near the headspring area. Clear spring water, stable sand and mud substrates, and relatively low stream flow (mean velocity <0.49 m/s) characterize both rivers [27, 34]. The abundance and diversity of rooted vascular plants has declined in both rivers over the last two decades [27, 35]; however, the rate of loss has differed between the two systems (Fig 1). The Chassahowitzka River is comprised of a relatively diverse assemblage of submersed aquatic plants compared to the Homosassa River, where open sand and mud substrate predominates [17, 27]. Filamentous macroalgae blooms occur during winter and spring in both systems, creating seasonal differences in vegetative habitat characteristics (Fig 2) [35]. Both rivers historically supported rich and diverse fish communities [17, 20, 35, 36].

Fig. 1. Long-term mean vegetation biomass estimates at the Chassahowitzka and Homosassa rivers, Florida.
Long-term mean vegetation biomass estimates at the Chassahowitzka and Homosassa rivers, Florida.
Note that sampling did not occur during 2001 and 2002.
Fig. 2. Photographic comparisons of shoreline and vegetative habitats within the Chassahowitzka and Homosassa Rivers.
Photographic comparisons of shoreline and vegetative habitats within the Chassahowitzka and Homosassa Rivers.
A) overview of the Chassahowitzka River channel and riparian habitats in Reach 1, B) mixed aquatic vegetation habitat in the Chassahowitzka River, C) dense patch of the rooted vascular plant, Vallisneria americana, observed during summer (July and August) in the Chassahowitzka River, D) large-scale seasonal bloom of filamentous macroalgae observed during winter (January and February) in the Chassahowitzka River, E) overview of the Homosassa River channel and riparian habitat in Reach 1, F) example of filamentous macroalgae habitat cover in the Homosassa River, G) patch of filamentous macroalgae habitat in the Homosassa River, and H) large-scale seasonal bloom of filamentous macroalgae observed during winter (January and February) in the Homosassa River.

Estimation of biomass and diet composition from field surveys

Licensed state biologists with the Florida Fish and Wildlife Commission served as project field operation leads during the sampling of collection of fishes. The research was conducted under University of Florida Project Number 00069469 and Florida Fish and Wildlife Commission (Commission) Agreement Number 07002. All field research was conducted in accordance with sampling permit requirement and standard agency protocols issued by the Commission and specific to the project. All sacrificed fishes were euthanized by hypothermic shock. Field sampling occurred over a three-year period from July 2007 to June 2010. Three study reaches were sampled in each river, representing a gradient from freshwater to brackish habitats. Table 1 lists the geographic coordinates of the upstream and downstream boundaries for each river reach. The reaches were located directly below the freshwater source springs (Reach 1), midway between the source springs and the salt marsh (Reach 2), and directly above the salt marsh (Reach 3). Submersed aquatic vegetation, macroinvertebrates, and small-bodied fishes were sampled during February and August in the first two years, and monthly in the third year [35]. Large-bodied fishes were sampled during January and July in the first two years using standardized mark-recapture electrofishing, and monthly in the third year [35, 36]. Small-bodied fishes were sampled by block net seine depletions [35, 36]. Macroinvertebrates were sampled by throw trap depletions [17], mesh sleeve grab sampling of aquatic vegetation, and by sediment coring. Aquatic vegetation was sampled by quadrat sampling at fixed, long term monitoring transects [35]. Large-bodied fish, small-bodied fish, and large crustacean catch data were corrected for incomplete detection and effort to estimate absolute abundances as described in companion papers focused on sampling methods [36, 37]. Absolute biomasses of fishes and invertebrates were estimated by multiplying the estimated abundances by the mean weight of individuals per study reach and year. Mean trophic group biomasses were estimated by a simple bootstrap (with replacement) of absolute biomass estimates across study reaches and years. Trophic group definitions of producers and consumers sampled from each of the river systems are listed in Table 2 and sampling methods used to estimate biomasses and diet compositions are summarized in Table 3 (see also [35, 36, 37] for additional details).

Tab. 1. Geographic coordinates of upstream and downstream boundaries of river reaches sampled for plants, invertebrates, and fishes in the Chassahowitzka and Homosassa rivers.
Geographic coordinates of upstream and downstream boundaries of river reaches sampled for plants, invertebrates, and fishes in the Chassahowitzka and Homosassa rivers.
The coordinates mark the midstream locations of the reach boundaries.
Tab. 2. Trophic groups and taxa composition included in the Ecopath trophic mass-balance model of the Chassahowitzka River food web.
Trophic groups and taxa composition included in the Ecopath trophic mass-balance model of the Chassahowitzka River food web.
Tab. 3. Data sources and references for the Ecopath trophic mass balance of the Chassahowitzka River food web.
Data sources and references for the Ecopath trophic mass balance of the Chassahowitzka River food web.
In the table header, P denotes trophic group production, B denotes biomass, and Q denotes consumption.

Trophic linkages were identified through analyses of diets from fish collected from 2007 to 2010. Large-bodied fishes were sampled for stomach contents by gastric lavage in the field, with exception of lake chubsucker (Erimyzon sucetta) and American eel (Anguilla rostrata), which were sacrificed and examined by dissection in the lab. All small-bodied fishes examined for stomach contents were sacrificed and analyzed by dissection in the lab. All sacrificed fishes were euthanized by hypothermic shock via submersion in an ice bath. The diet composition of fishes was characterized as percent frequency by dry mass of prey groups [35, 54]. To account for partially digested and unidentifiable fish and invertebrate prey items, we multiplied the mean proportion of unidentifiable stomach contents by the percent composition of identified prey taxa, then added the partitioned unidentified mass estimates to the observed mass of each prey group, and then calculated the percent prey frequency by dry mass. Diet information and production rates for invertebrates was gathered from published literature [3853] (Table 3). A predator-prey matrix was constructed to summarize the mean prey composition of each consumer trophic group (Table 4). To account for seasonality of migratory saltwater species foraging within the rivers, the diet composition of saltwater trophic groups was assumed to consist of 50% imported prey (equivalent to the approximate proportion of the year spent within the rivers versus the Gulf of Mexico [35]). This assumption was based on abundance estimates of gray snapper (Lutjanus griseus) and tidewater mojarra (Eucinostomus harengulus), the dominant saltwater large- and small-bodied fish species by biomass in each river. Additionally, terrestrial prey items (e.g., waterfowl, reptiles, terrestrial insects, and amphibians) were modeled as imported prey, similar to Gulf of Mexico imported energy sources for saltwater groups.

Tab. 4. Estimated diet composition of consumers within the Chassahowitzka River, Florida.
Estimated diet composition of consumers within the Chassahowitzka River, Florida.
Prey groups are listed in rows, and predator groups are listed in columns with reference numbers corresponding to the group number listed in column 1. Diet composition of fishes was based on mean percent dry mass in stomach samples taken over a three-year period. The sample sizes are shown in parentheses next to the trophic group name. The diet composition of invertebrates was based on published literature referenced in Table 3.

Trophic mass-balance model of a coastal river food web

The Ecopath modeling framework balances the annual production in biomass of individual trophic groups with losses to predation, harvest and migration, and the overall net change in biomass. Inputs for each trophic group included the estimated biomass, production to biomass ratio, consumption to biomass ratio, prey composition, and proportion of biomass contributed to the detrital pool versus biomass exported from the system.

Using information described in the previous sections, a trophic mass-balance ecosystem model of the Chassahowitzka River aquatic food web was developed using Ecopath [55, 56, 57]. Summaries of the basic inputs for the Ecopath model are provided in Table 5. Exploitation of individual commercial and recreational species was included as part of the total instantaneous mortality rate (Z). The Ecopath model balanced when the net change in biomass within the model was accounted for by the rates of predation, harvest, and net biomass change from growth for each trophic group [58].

Tab. 5. Basic inputs for the Ecopath trophic mass-balance model of the Chassahowitzka River food web.
Basic inputs for the Ecopath trophic mass-balance model of the Chassahowitzka River food web.
In the table header, P/B denotes the ratio of trophic group production to biomass, and Q/B denotes the ratio of consumption to biomass.

Time-dynamic simulation of vascular plant loss—Effects on coastal river fish and invertebrate communities

The Ecosim framework simulates trophic group biomass rates of change over time based on gains from prey consumption times food conversion efficiency (proportion of prey consumed converted to biomass), and losses to mortality, including predation, fishing (assumed zero for the coastal river model), and unexplained natural mortality. Starting with the balanced Ecopath model, we parameterized Ecosim to assess the role of aquatic vegetation in structuring trophic interactions represented in the Ecopath model, given alternative plant-consumer mediation assumptions (Fig 3). Four specific scenarios, each representing different predator-prey dynamics coupled to vegetative habitat, were simulated using forcing functions on the vascular plants and filamentous macroalgae, and predator-prey mediation functions on large- and small-bodied fishes. The forcing functions defined the magnitude and change in vegetative biomass seasonally (filamentous macroalgae) and annually over the long-term time series (vascular plants). The mediation functions modeled predator search efficiency rates as a nonlinear function of vegetative biomass (Fig 3) to simulate an increase in consumption rates of prey by predators at lower vegetative biomass.

Fig. 3. Ecosim model forcing and mediation functions used to simulate changes in primary production and trophic interactions associated with the loss of aquatic vascular plants and seasonal production of filamentous macroalgae within spring-fed, coastal rivers.
Ecosim model forcing and mediation functions used to simulate changes in primary production and trophic interactions associated with the loss of aquatic vascular plants and seasonal production of filamentous macroalgae within spring-fed, coastal rivers.

Scenario 1 served as a baseline of plant community effects with no change in predator search efficiency. A long-term shift in river plant community structure over the 30-year period was simulated using two biomass forcing functions. The first forcing function was applied to vascular plant biomass simulating a 10-year period of constant biomass equal to the average from field observations for the Chassahowitzka River, followed by a 10-year period of linear decline, and a terminal 10-year period of vascular plant biomass equal to 50% of the initial biomass. A second forcing function was applied to filamentous macroalgae that simulated cyclical production occurring seasonally based on observed seasonal mean biomass estimates from vegetation monitoring in the Chassahowitzka and Homosassa rivers over the period of study (Fig 3). The plant biomass forcing functions were tuned such that model predictions matched observations from long-term field sampling [35]. Note that these forcing functions were included in all model scenarios.

Scenario 2 applied a mediation function between vascular plant biomass and the prey search efficiency of large-bodied fishes (i.e., predator search efficiency for prey increased exponentially as plant density decreased, Fig 3), thus modeling the hypothesis of compensatory predator foraging efficiency at decreased plant biomass.

In contrast to scenario 2, scenario 3 applied a mediation function between filamentous macroalgae biomass and the prey search efficiency of small-bodied fishes (i.e., predator search efficiency for prey decreased exponentially as macroalgae density increased, Fig 3). This scenario modeled the hypothesis that dense filamentous macroalgae patches served as predation refugia for macroinvertebrates.

Scenario 4 included both the mediation function between vascular plants and large-bodied fishes of scenario 2 and the mediation function between filamentous macroalgae and small-bodied fishes of scenario 3 (Fig 3).

Comparison of model accuracy and ranking of alternative models

To estimate the mean predicted biomass of trophic groups under each modeled scenario and assess model prediction error (observed vs. predicted), predicted monthly biomass for each functional group was “sampled” at the same time periods as our field sampling efforts (i.e., submersed aquatic vegetation, macroinvertebrates, and small-bodied fishes were sampled in February and August; large-bodied fishes were sampled in January and July during the terminal three years of the simulation). Similarly, model-predicted diet compositions of selected fishes were estimated from the terminal years of the time series. From these simulated time series, diet compositions were compared for the different consumers across a range of trophic levels. The predicted trophic group biomass and diet compositions under each alternative Ecosim model scenario were then compared to the observed values of the Homosassa River, and these models were ranked based on the calculated error between observed and predicted values. The total absolute error was calculated separately for biomass estimates and fish diet compositions to compare the predictive accuracy between alternative models as follows:

where

obs Bi is the observed biomass of trophic group i within the Homosassa River,

pred Bi is the Ecosim predicted biomass of trophic group i under each modeled scenario,

n is the total number of trophic groups;

and

obs DCj is the observed diet composition of consumer j in the Homosassa River,

pred DCj is the Ecosim predicted diet composition of consumer j under each modeled scenario, and

c is the number of consumers that were sampled for diets and occurred in both rivers.

Biomasses and diet compositions were summarized by fractional trophic levels [56], and grouped by 0.5 intervals (Table 6). This distinction was based on the dominant prey of a trophic group, and differs from traditional trophic level definitions by whole integers. The characterization was based on observed differences in prey composition among consumers within a trophic level. For example, consumers in the 2 to 2.5 trophic range had greater than 50% primary producers as prey (grazers), and consumers in the 2.5 to 3.0 trophic range had greater than 50% grazers as prey (omnivores). Similarly, consumers in the 3 to 3.5 trophic level had omnivores as a dominant prey (primary predators), and consumers within the 3.5 to 4.0 trophic level had primary predators as predominant prey type (secondary predators). These generalizations allowed for more accurate synthesis of the trophic-level effects resulting from changes in vegetation.

Tab. 6. Definitions of trophic levels based on observed prey composition of consumers and Ecopath predicted fractional trophic level estimates.
Definitions of trophic levels based on observed prey composition of consumers and Ecopath predicted fractional trophic level estimates.

Results

Trophic groups biomasses and diet compositions from field surveys

Intensive field sampling of the Chassahowitzka and Homosassa rivers elucidated several distinct spatial and seasonal patterns (Fig 4) within the systems for filamentous macroalgae, vascular plant, invertebrate, and fish communities. High biomass of filamentous macroalgae (Genera: Chaetomorpha, Chara, Gracilaria, Lyngbya) occurred seasonally during winter in both rivers. Vascular plant (Species: Hydrilla verticillata, Myriophyllum spicatum, Najas guadalupensis, Potamogeton spp., Ruppia maritima, Vallisneria americana, Zannichellia palustris) biomass was higher in the Chassahowitzka River, compared to the Homosassa River where vascular plants were nearly absent (Fig 4). Macroinvertebrate biomass was high in filamentous macroalgae, with amphipods (Species: Gammarus spp., Corophium louisianum, Grandidierella bonnieroides, Hyalella azteca), gastropods (Family: Hydrobiidae), tanaids (Order: Tanaidacea), and larval insects (Orders or Suborders: Anisoptera, Coleoptera, Megaloptera, Trichoptera, Zygoptera; and Family: Chironomidae) the most common invertebrate taxa. We found larval insects and crayfish (Family: Cambaridae) commonly associated with vascular plants and in higher abundance and biomass in the Chassahowitzka River. Mud crabs (Families: Xanthidae and Grapsidae) were the only macroinvertebrate found in higher abundance and biomass in the Homosassa River across sampling events; however, invertebrates associated with filamentous macroalgae were also observed in greater biomass compared to the Chassahowitzka River during winter periods. The Chassahowitzka River generally supported a greater biomass of freshwater fishes than the Homosassa River (Fig 4). Within the Chassahowitzka River, freshwater small-bodied fishes (Genera: Lucania spp., Menidia spp., Notropis spp., Fundulus spp.) were highly abundant during summer and declined during winter. Florida gar (Lepisosteus platyrhincus) was the only freshwater fish species with higher abundance in the Homosassa River.

Fig. 4. Mean absolute biomass estimates of plants, macroinvertebrates, and fishes in the Chassahowitzka and Homosassa Rivers, Florida.
Mean absolute biomass estimates of plants, macroinvertebrates, and fishes in the Chassahowitzka and Homosassa Rivers, Florida.

Gray snapper (Lutjanus griseus) were the dominant saltwater fish observed in both rivers and demonstrated seasonal patterns in abundance and biomass (Fig 4). Immigration of juvenile gray snapper (ages 0, 1, and 2) into rivers occurred during November, peak biomass was observed during December to February, and emigration to the Gulf of Mexico occurred during March to April. During periods of increased snapper density, small-bodied fish biomass decreased sharply (Fig 4), with freshwater small-bodied fishes primarily restricted to filamentous macroalgae habitat. The dominant small-bodied fish during winter periods was tidewater mojarra (Eucinostomus harengulus), although other saltwater species were more abundant in winter compared to summer (e.g., Strongylura spp.). The biomass of several large-bodied species was greater in the Homosassa River relative to the Chassahowitzka River, including common snook (Centropomus undecimalis), red drum (Sciaenops ocellatus), catfish (Ariopsis felis, Bagre marinus) and striped mullet (Mugil cephalus). In contrast to other saltwater fishes, pinfish (Lagodon rhomboides) occurred in greater biomass in the Chassahowitzka River, with peak biomass observed during summer months and in association with vascular plants. In addition to observed seasonal patterns, fish species composition in both rivers demonstrated a longitudinal gradient of highest abundance of freshwater species in reach 1 with declining abundance and replacement of freshwater by marine species downstream (Fig 4).

We documented selective foraging on prey groups that were seasonally available (detailed results in [35]). Amphipods were consumed by most fishes, including sunfish (Lepomis spp.), gray snapper, juvenile largemouth bass (Micropterus salmoides), and pinfish (Table 5). Crayfish were predominant prey for largemouth bass in the Chassahowitzka River, while largemouth bass in the Homosassa consumed a greater proportion of fishes, blue crabs, and allochthonous prey, including bull frogs (Rana catesbeiana) and juvenile water fowl. Fishes in the Homosassa River foraged on mud crabs more often than in the Chassahowitzka River, which was observed in diets of at least six species. Gray snapper diets in both rivers contained a high proportion of small-bodied fishes, including Lucania spp. and tidewater mojarra.

Trophic mass-balance model

We found complex trophic interactions in the Chassahowitzka River models (Fig 5). Estimates of ecotrophic efficiency indicated high rates of transfer of invertebrate and small-bodied fish production to freshwater and marine fishes with values from 73–98% for select prey groups, including benthic invertebrates (Classes: Bivalvia, Copepoda, Nematoda, Oligochaeta, Ostracoda, Polychaeta), amphipods, blue crabs, other invertebrates associated with vegetation, and saltwater small-bodied fishes (Genera: Anchoa mitchilli., Eucinostomus spp., Gobiosoma spp., Leiostomus spp., Microgobius spp., Strongylura spp., Syngnathus spp., Trinectes spp.). Productivity rate estimates of some invertebrate and small-bodied fish groups had to be adjusted from observed values for the Ecopath model to balance (Table 4). This was expected as some estimates of trophic group production to biomass ratios (P/B) were based on literature from systems with higher temperature fluctuations than our spring systems [7, 22].

Fig. 5. Ecopath trophic flow diagram of the Chassahowitzka River food web.
Ecopath trophic flow diagram of the Chassahowitzka River food web.
The sizes of the circles represent the scale of absolute biomasses of trophic groups.

Predicted ecosystem responses to changes in aquatic vegetation

Time dynamic simulations of the balanced food web model predicted similar negative biomass responses of fishes and invertebrates to vascular plant loss across all scenarios (Fig 6). Scenario four was the best model in terms of biomass predictions, suggesting that key ecosystem characteristics may include: (1) bottom-up drivers of vascular plant loss and seasonal filamentous macroalgae production, (2) compensatory predator responses of increased prey search efficiency of large-bodied fishes at decreased vascular plant biomass, and (3) decreased prey search efficiency of small-bodied fishes at high filamentous macroalgae biomass (Fig 6 and Table 7). Model predictions of faunal community responses were most consistent with inter-system observed differences for large and small-bodied fishes and large crustaceans (e.g., crayfish, shrimp, blue crabs). Model predictions were less accurate for benthic and vegetation associated invertebrates (Fig 6 and Table 7). Predicted biomass declines were supported by field observations of grass shrimp (Palaemonetes spp.), crayfish, freshwater small-bodied fishes, lake chubsucker, pinfish, sunfish, and largemouth bass.

Fig. 6. Comparison of time dynamic ecosystem model predicted changes in mean biomass of trophic groups versus observed spatial differences between the Chassahowitzka and Homosassa rivers.
Comparison of time dynamic ecosystem model predicted changes in mean biomass of trophic groups versus observed spatial differences between the Chassahowitzka and Homosassa rivers.
Note that the size of the pie charts represent absolute biomasses within a trophic level, but are scaled to the same size across trophic levels in the Chassahowitzka River. The biomass ratios of trophic levels (1 to 2 to 2.5 to 3 to 3.5) in the Chassahowitzka River was approximately 1000 to 57 to 33 to 22 to 0.01.
Tab. 7. Absolute error between observed biomass and diet composition of trophic groups within the Homosassa River versus Ecosim predicted modeling of vascular plant loss and seasonal production of filamentous macroalgae under alternative hypotheses of plant mediation effects.
Absolute error between observed biomass and diet composition of trophic groups within the Homosassa River versus Ecosim predicted modeling of vascular plant loss and seasonal production of filamentous macroalgae under alternative hypotheses of plant mediation effects.
The values in the table are the absolute value of observed mean biomass and diet composition of fishes (measured as mean proportion dry mass of prey groups) in the Homosassa River minus the Ecopath predicted estimates.

Ecosim-predicted diet compositions of fish consumers were similar to observed compositions (Fig 7, Table 7). Scenario three had the best predictive capability for observed diet compositions, accurately describing many changes in prey composition for predator groups and reflecting spatial and seasonal differences in prey abundance. For example, pinfish (trophic level 2.5) diets correctly showed increased proportions of amphipods and benthic invertebrates and decreased proportions of vascular plants, while trophic level 3 consumer diets correctly showed increased proportions of saltwater small-bodied fishes and mud crabs and decreased composition of amphipods. Trophic level 3.5 consumers correctly showed increased proportions of saltwater small-bodied fishes, and consumers across all trophic levels correctly showed a decreased proportion of crayfish in diets (Fig 7). None of the models predicted the increased magnitude of mud crabs as prey composition for fishes, indicating that this prey group, along with other benthic and filamentous macroalgae associated invertebrates, may be unrecognized and important food sources for fishes in coastal rivers when vascular plants are sparse.

Fig. 7. Comparison of time dynamic ecosystem model predicted changes in diet compositions of select fishes versus observed spatial differences in diet composition between the Chassahowitzka and Homosassa rivers.
Comparison of time dynamic ecosystem model predicted changes in diet compositions of select fishes versus observed spatial differences in diet composition between the Chassahowitzka and Homosassa rivers.
Pinfish comprised trophic level 2.5 consumers; Lepomis spp., gray snapper, red drum, and sheepshead comprised trophic level 3 consumers; and largemouth bass and common snook comprised trophic level 3.5 consumers.

Discussion

Key results from our field and model based assessments include: (1) submersed vascular plants play a central role in coastal river food webs, likely through a combination of production characteristics and mediated trophic interactions; (2) filamentous macroalgae appear to provide refuge habitat and harbors high densities and biomass of some macroinvertebrates compared to vascular plants; (3) crustaceans and small-bodied fishes in these systems provide important linkages of energy transfer from primary producers to large-bodied fishes; and, (4) the loss of vascular plants from spring-fed coastal rivers likely negatively affects the majority of invertebrates and fishes across multiple trophic levels.

Our findings indicate a possible linkage between bottom-up and top-down controls in coastal, spring-fed rivers. Plant loss is likely to affect the search efficiency of predators through decreased primary production effects on prey availability and altered predator search efficiency rates [12, 15, 59]. Our results also support the hypothesis that high plant densities adversely affects the feeding efficiency of fishes and helps sustain high densities of prey taxa [60], which may be one reason for the observed high biomass and density of select invertebrates associated with filamentous macroalgae. We found improved model predictive capability to spatially discrete biomass observations when compensatory predator search efficiencies at low vegetation biomass were included in our analysis. Modeling this response actually better explained many of the observed patterns in community structures of the coastal rivers compared to alternative models that excluded compensatory predator foraging efficiency. However, we note that our model selection approach does not account for increased model complexity due to the addition of parameters associated with the plant mediation functions. We consider this limitation unimportant given the total number of parameters in the ecosystem model, because our alternative hypotheses were outlined a priori, and since our major objective was to best predict changes in river community biomass and trophic interactions associated with plant loss and replacement by filamentous macroalgae. Analyses that excluded compensatory foraging by large-bodied fishes predicted sharp population biomass declines compared to the observed biomass difference between the Chassahowitzka and Homosassa rivers. This may explain why we observed relatively low biomasses of small-bodied fishes and higher crustacean biomass in the Homosassa River–these groups may be highly susceptible to fish predators at low vascular plant biomass. Camp et al. [26] demonstrated the importance of aquatic vegetation as small-bodied fish predation refugia through tethering experiments of rainwater killifish (Lucania parva), concluding that predation on small-bodied fishes was greater in open substrates compared to patches of vascular plants and filamentous macroalgae within the Chassahowitzka River. Kornijów et al. [60] found that the presence of a fish predator influenced the habitat use, abundance, and size structure of Gammarus amphipods in a stream ecosystem, and concluded that vascular plants facilitated the coexistence of fish predator and invertebrate prey at high densities. We found similar results with many invertebrate taxa occurring in high density in plant habitats, particularly Gammarus spp. in filamentous algae, as well as small-bodied fishes in vascular plant colonies. In combination, the results of experimental studies in shallow aquatic ecosystems, and the findings from our field observations and ecosystem model predictions, highlight the importance of both top-down and bottom-up processes in structuring spring-fed, coastal river communities.

We hypothesized that filamentous macroalgae would mitigate predation risk to some aquatic invertebrates through reduced predator foraging rates, while at the same time competing with rooted vascular plants for light, nutrients, and other resources. We found high biomass of some macroinvertebrates in filamentous macroalgae that can be explained by decreased search efficiency of predatory small-bodied fishes. Model error was improved in terms of predicted biomass and trophic interactions of invertebrate feeders when these predator-prey interactions were included. Differences in the observed and predicted biomasses of mud crabs and vegetation-associated invertebrates suggests these trophic groups were not accurately represented in our model. Macroinvertebrate diet habits and rates of prey consumption in these systems are poorly understood, and as a result, these trophic groups demonstrated the greatest error in predicted biomass accounting for over 77% of the total model error across all projection scenarios. This is potentially due to uncertainties in how these functional groups may respond to changes in available prey resources, and possible model misspecification of insect herbivore top-down effects on vascular plant biomass [61]. Another explanation for the discrepancy between observed and predicted small macroinvertebrate biomass is the assumption of a perfect detection in sampling. Unlike fish and larger invertebrates where detection probability was estimated [36, 37], we assumed a detection probability of 1.0 for small macroinvertebrates associated with plant habitats, which may have resulted in a negative bias in abundance and biomass estimates. Regardless of this potential negative bias, the observed responses in macroinvertebrate biomass were in stark contrast to fishes and large crustaceans, which showed a negative response to the loss of vascular plants and large-scale production of filamentous macroalgae. The various influences that affect production of invertebrates in filamentous macroalgae patches remain largely unknown and are a notable area of model uncertainty.

Empirical estimates of seasonal trophic group biomasses in each river demonstrated the dynamic community structure of these systems. During summer when vascular plant biomass was highest and filamentous macroalgae biomass was lowest, macroinvertebrate biomass was lowest, small-bodied fish biomass was highest, and large-bodied fish biomass was lowest (primarily due to emigration of marine fishes during spring). During winter, vascular plant biomass was lowest, filamentous macroalgae biomass was highest, specific invertebrate prey group (i.e., amphipods, vegetative invertebrates, mud crabs) biomasses were highest in filamentous macroalgae, small-bodied fish biomass was lowest, and the densities of marine large-bodied fish were highest (due to large-scale immigration of marine fishes in fall). For many trophic groups, model predictions matched field observations of seasonal biomass and trophic group prey compositions. Patterns in seasonal community composition were best explained by model scenario four, which incorporated compensatory search efficiency of large-bodied fishes at low vascular plant biomass during summer, and depensatory search efficiency of small-bodied fishes at high filamentous macroalgae biomass during winter.

We found that the loss of vascular plants from a coastal river ecosystem may alter the composition of the aquatic community and food web structure, and result in a net decline in the biomass of higher trophic levels, including fishes. We documented declines of specific freshwater and marine trophic groups at low vascular plant density and biomass, increased biomass of some invertebrate trophic groups associated with filamentous macroalgae biomass, and a resultant shift in fish and invertebrate faunal community composition. Our results are consistent with the findings of other researchers who have demonstrated plant loss effects on freshwater [62] and marine communities and changes in trophic dynamics [63, 64], as well as the importance of structural habitat in maintaining community structure [65]. Similar to Bettoli et al. [62], we concluded that the greatest population effects of vascular plant loss occurred for freshwater phytophilic taxa in spring-fed, coastal rivers. These large-scale ecological changes can potentially result in the loss of key species and altered food webs with implications for management of species-level biodiversity and ecosystem function [66].

The loss of grazers and detritivores from coastal rivers, including lake chubsucker and crayfish, could result in a negative feedback on vascular plant production. Lake chubsucker may utilize vegetative habitat to forage or as refugia, and were historically common in the Homosassa River when vascular plants were prevalent [21]. The loss of vascular plant habitat could have negatively affected lake chubsucker foraging success or survival and potentially led to the extirpation of this species from portions of the river. Decline of this important herbivorous fish in the Homosassa River may have resulted in decreased grazing of periphyton, increased shading of vascular plants, and accelerated plant loss in the ecosystem [4, 67], ultimately resulting in a vegetative community comprised exclusively of seasonally abundant filamentous macroalgae. Heffernan et al. [18] proposed a similar hypothesis of decreased grazer abundance resulting in the accelerated extirpation of vascular plants within other spring-fed rivers, although the researchers propose dissolved oxygen limitation as a potential casual mechanism of grazer decline. Wood et al. [61] propose an alternative hypothesis of grazer regulated plant biomass, with systems containing low herbivore diversity experiencing higher magnitude of vascular plant loss compared to high grazer diversity systems. We measured low fish grazer diversity in both systems; however, the biomass and diversity of invertebrates classified as grazers was a key source of uncertainty in our model. While our ecosystem modelling approach and incorporation of alternative plant-consumer mediation scenarios allows for these mechanistic types of predator-prey hypotheses to be evaluated, further experimental research is needed to gain a mechanistic understanding of grazer-producer dynamics in ecosystems.

Spring discharge flow regulated river systems in Florida have been historically described as homeostatic in their chemical, physical and biological characteristics [22]. Our data suggest that the spring-fed rivers studied as part of this effort are temporally dynamic with regard to their vegetative characteristics and composition and biomass of organisms that occupy the systems. The observed differences in population densities, biomass, and diets of fishes are evidence that changes in vegetative habitat disproportionately impact individual species, and continued changes to vegetation communities are likely to alter the fish and invertebrate communities in these systems. Mechanisms leading to the loss of rooted vascular plants in Florida’s springs and associated downstream waters are poorly understood; yet present restoration efforts are focused on reducing nutrient inputs and increasing flow through protection of groundwater resources and recharge areas. Our results suggest that successful plant restoration efforts are likely to result in a net increase in overall fish biomass, but that not all trophic groups will equally benefit. The complex dynamics between vascular plant biomass and consumer foraging efficiency, and filamentous macroalgae production and prey abundance, are important factors influencing the predator-prey dynamics within these systems and, in turn, the abundance and biomass of fishes and invertebrates.

Supporting information

S1 Zip File [zip]
Chassahowitzka River Ecopath with Ecosim model.

S2 Zip File [zip]
Description of data files, database fields, and data codes used in the coastal river monitoring databases.

S3 Zip File [zip]
Electrofishing catchability estimates of fish sampled at the Chassahowitzka and Homosassa rivers.

S4 Zip File [zip]
Electrofishing sampling data collected at the Chassahowitzka and Homosassa rivers.

S5 Zip File [zip]
Diet observations of fishes collected at the Chassahowitzka and Homosassa rivers.

S6 Zip File [zip]
Invertebrate sampling data collected at the Chassahowitzka and Homosassa rivers.

S7 Zip File [zip]
Submersed aquatic vegetation sampling data collected at the Chassahowitzka and Homosassa rivers.

S8 Zip File [zip]
Compiled invertebrate databases collected at the Chassahowitzka and Homosassa rivers.

S9 Zip File [zip]
Seine sampling data collected at the Chassahowitzka and Homosassa rivers.

S10 Zip File [zip]
Seine captured species length-weight data collected at the Chassahowitzka and Homosassa rivers.


Zdroje

1. Duarte CM. The future of seagrass meadows. Environmental conservation. 2002 Jun;29(2):192–206.

2. Orth RJ, Carruthers TJ, Dennison WC, Duarte CM, Fourqurean JW, Heck KL, et al. A global crisis for seagrass ecosystems. Bioscience. 2006 Dec 1;56(12):987–96.

3. Waycott M, Duarte CM, Carruthers TJ, Orth RJ, Dennison WC, Olyarnik S, et al. Accelerating loss of seagrasses across the globe threatens coastal ecosystems. Proceedings of the national academy of sciences. 2009 Jul 28;106(30):12377–81.

4. Duarte CM. Submerged aquatic vegetation in relation to different nutrient regimes. Ophelia. 1995 Feb 1;41(1):87–112.

5. Carpenter SR, Lodge DM. Effects of submersed macrophytes on ecosystem processes. Aquatic botany. 1986 Jan 1;26:341–70.

6. Jeppesen E, Sondergaard M, Sondergaard M, Christofferson K, editors. The structuring role of submerged macrophytes in lakes. Springer Science & Business Media; 2012 Dec 6.

7. Hauxwell J, Frazer TK, Osenberg CW. An annual cycle of biomass and productivity of Vallisneria americana in a subtropical spring-fed estuary. Aquatic Botany. 2007 Jul 1;87(1):61–8.

8. Barko JW, James WF. Effects of submerged aquatic macrophytes on nutrient dynamics, sedimentation, and resuspension. InThe structuring role of submerged macrophytes in lakes 1998 (pp. 197–214). Springer, New York, NY.

9. Caraco N, Cole J, Findlay S, Wigand C. Vascular plants as engineers of oxygen in aquatic systems. BioScience. 2006 Mar 1;56(3):219–25.

10. Gregg W. W., and Rose F. L. 1982. The effects of aquatic macrophytes in the stream micro-environment. Aquatic Botany 14:309–324.

11. Dodds WK, Biggs BJ. Water velocity attenuation by stream periphyton and macrophytes in relation to growth form and architecture. Journal of the North American Benthological Society. 2002 Mar 1;21(1):2–15.

12. Power ME. Top‐down and bottom‐up forces in food webs: do plants have primacy. Ecology. 1992 Jun;73(3):733–46.

13. Savino JF, Stein RA. Predator‐prey interaction between largemouth bass and bluegills as influenced by simulated, submersed vegetation. Transactions of the American Fisheries Society. 1982 May 1;111(3):255–66.

14. Huffaker C. Experimental studies on predation: dispersion factors and predator-prey oscillations. Hilgardia. 1958 Aug 1;27(14):343–83.

15. Crowder LB, Cooper WE. Habitat structural complexity and the interaction between bluegills and their prey. Ecology. 1982 Dec 1;63(6):1802–13.

16. Harrison SS, Bradley DC, Harris IT. Uncoupling strong predator–prey interactions in streams: the role of marginal macrophytes. Oikos. 2005 Mar;108(3):433–48.

17. Camp EV, Staudhammer CL, Pine WE, Tetzlaff JC, Frazer TK. Replacement of rooted macrophytes by filamentous macroalgae: effects on small fishes and macroinvertebrates. Hydrobiologia. 2014 Jan 1;722(1):159–70.

18. Heffernan JB, Liebowitz DM, Frazer TK, Evans JM, Cohen MJ. Algal blooms and the nitrogen‐enrichment hypothesis in Florida springs: evidence, alternatives, and adaptive management. Ecological Applications. 2010 Apr 1;20(3):816–29. doi: 10.1890/08-1362.1 20437966

19. Burghart SE, Jones DL, Peebles EB. Variation in estuarine consumer communities along an assembled eutrophication gradient: implications for trophic instability. Estuaries and coasts. 2013 Sep 1;36(5):951–65.

20. Odum HT. Factors controlling marine invasion into Florida fresh waters. Bulletin of Marine Science. 1953 Mar 1;3(2):134–56.

21. Herald ES, Strickland RR. An annotated list of the fishes of Homosassa Springs, Florida. Quarterly Journal of the Florida Academy of Sciences. 1948 Dec 1;11(4):99–109.

22. Odum HT. Primary Production Measurements in Eleven Florida Springs and a Marine Turtle‐Grass Community 1. Limnology and Oceanography. 1957 Apr;2(2):85–97.

23. Yobbi DK, Knochenmus LA. Salinity and flow relations and effects of reduced flow in the Chassahowitzka River and Homosassa River estuaries, Southwest Florida. Water-Resources Investigations Report. 1989;88:4044.

24. Yobbi DK. Effects of tidal stage and ground-water levels on the discharge and water quality of springs in coastal Citrus and Hernando Counties, Florida. Water-Resources Investigations Report. 1992;92:4069.

25. Katz BG. Sources of nitrate contamination and age of water in large karstic springs of Florida. Environmental Geology. 2004 Oct 1;46(6–7):689–706.

26. Camp EV, Gwinn DC, Pine WE III, Frazer TK. Changes in submersed aquatic vegetation affect predation risk of a common prey fish Lucania parva (Cyprinodontiformes: Fundulidae) in a spring‐fed coastal river. Fisheries Management and Ecology. 2012 Jun;19(3):245–51.

27. Frazer TK, Notestein SK, Pine WE Jr. Changes in the physical, chemical and vegetative characteristics of the Homosassa, Chassahowitzka and Weeki Wachee Rivers. Final Report. Prepared for the Southwest Florida Water Management District. Brooksville, FL. 2006 Aug.

28. Stevenson RJ, Pinowska A, Albertin A, Sickman JO. Ecological condition of algae and nutrients in Florida springs: the synthesis report. Tallahassee, Florida: Florida Department of Environmental Protection; 2007 Oct 31.

29. Liebowitz DM, Cohen MJ, Heffernan JB, Korhnak LV, Frazer TK. Environmentally‐mediated consumer control of algal proliferation in Florida springs. Freshwater biology. 2014 Oct;59(10):2009–23.

30. Mumma MT, Cichra CE, Sowards JT. Effects of recreation on the submersed aquatic plant community of Rainbow River, Florida. Journal of Aquatic Plant Management. 1996 Jul 1;34:53–6.

31. Buckingham CA, Lefebvre LW, Schaefer JM, Kochman HI. Manatee response to boating activity in a thermal refuge. Wildlife Society Bulletin. 1999 Jul 1:514–22.

32. King JM, Heinen JT. An assessment of the behaviors of overwintering manatees as influenced by interactions with tourists at two sites in central Florida. Biological Conservation. 2004 May 1;117(3):227–34.

33. Scott TM, Means GH, Meegan RP, Means RC, Upchurch S, Copeland RE, Jones J, Roberts T, Willet A. Springs of Florida. Tallahassee, Florida; Florida Geological Survey; 2004.

34. Hoyer M, Frazer T, Notestein S. Vegetative characteristics of three low-lying Florida coastal rivers in relation to flow, light, salinity and nutrients. Hydrobiologia. 2004 Oct 1;528(1–3):31–43.

35. Frazer TK, Pine WE III, Lauretta MV, Warren G, Nagid E, Strong W, Tuten T. Increased nutrient loading of spring-fed coastal rivers: effects on habitat and faunal communities. Final report. Florida Fish and Wildlife Conservation Commission, Tallahassee, FL. 2011.

36. Lauretta MV, Camp EV, Pine WE III, Frazer TK. Catchability model selection for estimating the composition of fishes and invertebrates within dynamic aquatic ecosystems. Canadian journal of fisheries and aquatic sciences. 2013 Jan 3;70(3):381–92.

37. Camp EV, Gwinn DC, Lauretta MV, Pine WE, Frazer TK. Use of recovery probabilities can improve sampling efficiency for throw traps in vegetated habitats. Transactions of the American Fisheries Society. 2011 Mar;140(1):164–9.

38. Walters C, Martell SJ, Christensen V, Mahmoudi B. An Ecosim model for exploring Gulf of Mexico ecosystem management options: implications of including multistanza life-history models for policy predictions. Bulletin of Marine Science. 2008 Jul 1;83(1):251–71.

39. Kevrekidis T, Kourakos G, Boubonari T. Life history, reproduction, growth, population dynamics and production of Gammarus aequicauda (Crustacea: Amphipoda) at extremely low salinities in a Mediterranean lagoon. International Review of Hydrobiology. 2009 Jun;94(3):308–25.

40. Subida MD, Cunha MR, Moreira MH. Life history, reproduction, and production of Gammarus chevreuxi (Amphipoda: Gammaridae) in the Ria de Aveiro, northwestern Portugal. Journal of the North American Benthological Society. 2005 Mar;24(1):82–100.

41. Robertson AI. The relationship between annual production: biomass ratios and lifespans for marine macrobenthos. Oecologia. 1979 Jan 1;38(2):193–202. doi: 10.1007/BF00346563 28308889

42. Dittel AI, Epifanio CE, Fogel ML. Trophic relationships of juvenile blue crabs (Callinectes sapidus) in estuarine habitats. Hydrobiologia. 2006 Sep 1;568(1):379–90.

43. Reichmuth JM, Roudez R, Glover T, Weis JS. Differences in prey capture behavior in populations of blue crab (Callinectes sapidus Rathbun) from contaminated and clean estuaries in New Jersey. Estuaries and Coasts. 2009 Mar 1;32(2):298–308.

44. Seitz RD, Lipcius RN, Seebo MS. Food availability and growth of the blue crab in seagrass and unvegetated nurseries of Chesapeake Bay. Journal of Experimental Marine Biology and Ecology. 2005 Jun 1;319(1–2):57–68.

45. Mascaró M, Castillo AM, Simoes N, Chiappa-Carrara X. Variations in the feeding habits of Callinectes rathbunae in Las Palmas lagoon (southern Gulf of Mexico) on three temporal scales. Crustaceana. 2007 Feb 1:139–60.

46. Rosas C, Lazaro-Chavez E, Bückle-Ramirez F. Feeding habits and food niche segregation of Callinectes sapidus, C. rathbunae, and C. similis in a subtropical coastal lagoon of the Gulf of Mexico. Journal of Crustacean Biology. 1994 Apr 1;14(2):371–82.

47. Gutiérrez-Yurrita PJ, Sancho G, Bravo MA, Baltanas A, Montes C. Diet of the red swamp crayfish Procambarus clarkii in natural ecosystems of the Donana National Park temporary fresh-water marsh (Spain). Journal of Crustacean Biology. 1998 Jan 1;18(1):120–7.

48. Kneib RT, Weeks CA. Intertidal distribution and feeding habits of the mud crab, Eurytium limosum. Estuaries. 1990 Dec 1;13(4):462–8.

49. Collins PA. Feeding of Palaemonetes argentinus (Decapoda: Palaemonidae) from an oxbow lake of the Paraná River, Argentina. Journal of Crustacean Biology. 1999 Jul 1;19(3):485–92.

50. Morgan MD. Grazing and predation of the grass shrimp Palaemonetes pugio 1. Limnology and Oceanography. 1980 Sep;25(5):896–902.

51. Costantini ML, Rossi L. Laboratory study of the grass shrimp feeding preferences. Hydrobiologia. 2001 Jan 1;443(1–3):129–36.

52. MacNeil C, Dick JT, Elwood RW. The trophic ecology of freshwater Gammarus spp.(Crustacea: Amphipoda): problems and perspectives concerning the functional feeding group concept. Biological Reviews. 1997 Aug;72(3):349–64.

53. Duffy JE, Harvilicz AM. Species-specific impacts of grazing amphipods in an eelgrass-bed community. Marine Ecology Progress Series. 2001 Nov 28;223:201–11.

54. Chipps SR, Garvey JE. Assessment of food habits and feeding patterns. Analysis and interpretation of freshwater fisheries data. American Fisheries Society, Bethesda, Maryland. 2007:473–514.

55. Walters C, Christensen V, Pauly D. Structuring dynamic models of exploited ecosystems from trophic mass-balance assessments. Reviews in fish biology and fisheries. 1997 Jun 1;7(2):139–72.

56. Pauly D, Christensen V, Walters C. Ecopath, Ecosim, and Ecospace as tools for evaluating ecosystem impact of fisheries. ICES journal of Marine Science. 2000 Jun 1;57(3):697–706.

57. Christensen V, Walters CJ. Ecopath with Ecosim: methods, capabilities and limitations. Ecological modelling. 2004 Mar 1;172(2–4):109–39.

58. Walters CJ, Martell SJ. Fisheries ecology and management. Princeton University Press; 2004 Nov 7.

59. Bettoli PW, Maceina MJ, Noble RL, Betsill RK. Piscivory in largemouth bass as a function of aquatic vegetation abundance. North American Journal of Fisheries Management. 1992 Aug;12(3):509–16.

60. Kornijów R, Measey GJ, Moss B. The structure of the littoral: effects of waterlily density and perch predation on sediment and plant‐associated macroinvertebrate communities. Freshwater biology. 2016 Jan;61(1):32–50.

61. Wood KA, O'hare MT, McDonald C, Searle KR, Daunt F, Stillman RA. Herbivore regulation of plant abundance in aquatic ecosystems. Biological Reviews. 2017 May;92(2):1128–41. doi: 10.1111/brv.12272 27062094

62. Bettoli PW, Maceina MJ, Noble RL, Betsill RK. Response of a reservoir fish community to aquatic vegetation removal. North American Journal of Fisheries Management. 1993 Feb 1;13(1):110–24.

63. Deegan LA, Wright A, Ayvazian SG, Finn JT, Golden H, Merson RR, Harrison J. Nitrogen loading alters seagrass ecosystem structure and support of higher trophic levels. Aquatic Conservation: Marine and Freshwater Ecosystems. 2002 Mar;12(2):193–212.

64. Coll M, Schmidt A, Romanuk T, Lotze HK. Food-web structure of seagrass communities across different spatial scales and human impacts. PloS one. 2011 Jul 21;6(7):e22591. doi: 10.1371/journal.pone.0022591 21811637

65. Sass GG, Kitchell JF, Carpenter SR, Hrabik TR, Marburg AE, Turner MG. Fish community and food web responses to a whole‐lake removal of coarse woody habitat. Fisheries. 2006 Jul;31(7):321–30.

66. Dobson A, Lodge D, Alder J, Cumming GS, Keymer J, McGlade J, Mooney H, Rusak JA, Sala O, Wolters V, Wall D. Habitat loss, trophic collapse, and the decline of ecosystem services. Ecology. 2006 Aug;87(8):1915–24. doi: 10.1890/0012-9658(2006)87[1915:hltcat]2.0.co;2 16937628

67. Roberts E, Kroker J, Körner S, Nicklisch A. The role of periphyton during the re-colonization of a shallow lake with submerged macrophytes. Hydrobiologia. 2003 Nov 1;506(1–3):525–30.


Článok vyšiel v časopise

PLOS One


2019 Číslo 12
Najčítanejšie tento týždeň
Najčítanejšie v tomto čísle
Kurzy

Zvýšte si kvalifikáciu online z pohodlia domova

Aktuální možnosti diagnostiky a léčby litiáz
nový kurz
Autori: MUDr. Tomáš Ürge, PhD.

Všetky kurzy
Prihlásenie
Zabudnuté heslo

Zadajte e-mailovú adresu, s ktorou ste vytvárali účet. Budú Vám na ňu zasielané informácie k nastaveniu nového hesla.

Prihlásenie

Nemáte účet?  Registrujte sa

#ADS_BOTTOM_SCRIPTS#