Open Access
1 March 2015 Aquatic Vertebrate Predation Threats to the Platte River Caddisfly (Trichoptera: Limnephilidae)
Michael C. Cavallaro, Lindsay A. Vivian, W. Wyatt Hoback
Author Affiliations +

The Platte River caddisfly, Ironoquia plattensis Alexander & Whiles (Trichoptera: Limnephilidae), was once the most abundant component of the benthic macroinvertebrate community in Platte River backwater sloughs, attaining larval densities of approximately 1,000 individuals per m2 and accounting for approximately 40% of the emerging secondary production. Surveys for the species conducted between 1999 and 2004 found 6 sites with I. plattensis, and recent sampling has found 29 additional sites with the caddisfly; however, only one population has densities comparable to those found at the type locality. Backwater sloughs where I. plattensis occur provide habitat for a variety of aquatic vertebrates which could potentially threaten the species' persistence. This project tested the ability of seven fish species and a tadpole to consume I. plattensis larvae. Replicated experiments presented vertebrates with 3 early instar I. plattensis larvae in 9.5 liter aquaria. Based on Kruskal-Wallis one-way ANOVA (P = 0.05), significant predation was observed only with brook stickleback, Culaea inconstans Kirtland (Gasterosteiformes: Gasterosteidae), feeding trials. C. inconstans consumed a mean of 0.49 I. plattensis larvae per 24 h. Our results suggest I. plattensis populations may be reduced by the presence of brook stickleback in backwater sloughs. Alterations to the Platte River may increase the chances for I. plattensis and C. inconstans habitat overlap from greater river connectivity.

Trophic interactions can shape aquatic macroinvertebrate assemblages and alter food webs depending on habitat type and complexity (Wellborn et al. 1996). In permanent freshwater aquatic systems, fish are the dominant predators of aquatic invertebrates (Wissinger et al. 1999). Intermittent and ephemeral habitats with regular disturbance support a variety of invertebrate predators, including dragonflies (Batzer & Wissinger 1996), hempiterans, beetle larvae, and amphibians such as frogs (Wellborn et al. 1996) and salamanders (Wissinger et al. 1999). Fish may also seasonally invade temporary waters especially when connections to a permanent water body occur via hydrologic events (Chapman & Warburton 2006; Hodges & Magoulick 2011). This hydrologic variability is often displayed in a braided river system such as the Platte River (Eschner et al. 1981; Whiles & Goldowitz 2005).

The Platte River caddisfly, Ironoquia plattensis Alexander & Whiles (Trichoptera: Limnephilidae), is a benthic macroinvertebrate adapted to the intermittent hydrology of backwater sloughs in central Nebraska and is likely endemic to the state as well (Whiles et al. 1999). Unlike most other caddisflies, members of the Ironoquia genus migrate to land as fifth instars (Williams & Williams 1975; Whiles et al. 1999). The transition to its terrestrial life stage coincides with an increase in water temperatures and is associated with seasonal drying (Whiles et al. 1999). In 2004, I. plattensis numbers had declined substantially at known sites including the type locality for the species (Alexander & Whiles 2000; Goldowitz 2004). Subsequent surveys in 2007 found I. plattensis to be absent from two previously occupied sites (Vivian et al. 2013). It was recently considered for protection under the Endangered Species Act (USFWS 2012). Currently, I. plattensis occurs in disjunct, fragmented populations along the Platte, Loup, and Elkhorn river systems at historically low densities (Vivian et al. 2013).

Temporary aquatic habitats, such as backwater areas and intermittent wetlands, serve as important nursery grounds for fish species (Sheaffer & Nickum 1986), and backwater sloughs that support various fish species are common along the major river systems in the Great Plains. The dynamic hydrology within the Great Plains is responsible for more distinct, less diverse aquatic communities when compared with more permanent systems (Dodds et al. 2004). Several species of fish were found at the type locality of I. plattensis including the plains topminnow, Fundulus sciadicus Cope, common carp, Cyprinus carpio L., and brassy minnow, Hybognathus hankinsoni Hubbs (Whiles et al. 1999). Fish surveys in 2007–2012 found native fish species in sloughs with extant I. plattensis populations. These species included fathead minnow, Pimephales promelas Rafinesque, black bullhead, Ameiurus melas Rafinesque, Iowa darter, Etheostoma exile Girard, and green sunfish, Lepomis cyanellus Rafinesque, and introduced western mosquitofish, Gambusia affinis Baird & Girard (Vivian 2010). In addition to fish, Whiles et al. (1999) also found adult and larval plains leopard frogs, Lithobates blairi Mecham, Littlejohn, Oldham, Brown, & Brown, western chorus frogs, Pseudacris triseriata Wied-Neuwied, and Woodhouse's toads, Anaxyrus woodhousii Girard at the I. plattensis type locality. Recent I. plattensis surveys have found American bullfrog, Lithobates catesbeianus Shaw, tadpoles and adults at occupied sloughs (Cavallaro, personal observation).

The reasons for the limited distribution and range of population sizes of I. plattensis have not been fully identified. The alterations to the river systems in Nebraska, specifically the Platte River, influence the connectivity of I. plattensis habitat to the main river channels. These changes indirectly facilitate the colonization and abundance of fish and amphibians, which otherwise may not occur. The goal of the present research was to evaluate the potential for vertebrate predation on early I. plattensis instars by direct observation under laboratory conditions.

Materials and Methods

To quantify fish and larval amphibian predation on I. plattensis, we conducted a series of laboratory experiments at the University of Nebraska at Kearney ecology laboratory. Experiments were conducted using second and third instar I. plattensis to provide a more accurate representation to predation vulnerability. During this development stage, larvae are active, above the benthic substrate, and more prone to predation. Ironoquia plattensis were obtained from a backwater area along the Platte River near Gibbon, Nebraska. Brook stickleback, western mosquitofish, Iowa darter, black bullhead, fathead minnow, and green sunfish were collected by seining from a backwater slough on the Platte River near Kearney, Nebraska. Bullfrog tadpoles were purchased from Carolina Biological Inc. (Burlington, North Carolina). Plains topminnows were collected from a production pond located at Sacramento- Wilcox Wildlife Management Area near Holdrege, Nebraska.

Vertebrate predators were fed freeze-dried bloodworms and veggie rounds (Omega One®, Ferndale, New York) ad libitum for 72 h before each trial. For each trial, fifteen 9.5 liter (2.5 gal) aquaria were placed in a Percival® environmental chamber (Percival Scientific, Inc., Perry, Iowa). To simulate spring conditions when larvae are early instars, chambers were set to a 14:10 h L:D, at 50% RH, and a constant temperature of 10.0 ± 1.0 °C.

Before the beginning of each trial, all fish and tadpoles were measured to the nearest 1.0 mm, and larval cases were measured to the nearest 0.1 mm using a digital caliper. Large predators (e.g., green sunfish and black bullhead) used were no greater than 10 cm to mimic the size of naturally occurring populations surveyed at sites occupied by I. plattensis. All measured larvae were placed in a 250 mL beaker. For each laboratory trial, 5.6 L (1.5 gal) of water was placed into 9.5 liter (2.5 gal) aquaria. Three randomly selected 2nd and 3rd instars were placed into each tank along with a single vertebrate predator. Fifteen replicates were performed for each predator species. For all trials, an additional control aquarium contained 3 larvae and no predator. Additional tests were performed with brook stickleback by providing larvae with approximately 3 cm of leaf detritus added to the aquaria as refuge.

During the 72 h test period only caddisfly larvae were offered as a source of food. The number of living caddisflies was enumerated after intervals of 24, 48, and 72 h for each replicate, and daily consumption rates were calculated for each vertebrate species. These data were not normally distributed and thus, the number of consumed larvae was compared among species using a Kruskal-Wallis one-way ANOVA followed by a Dunn's test (Sigma Plot, Systat Software, Inc., San Jose, California USA). An IACUC permit was issued by the University of Nebraska at Kearney which approved the methodology used for this study.


There was a significant difference in predation of early instar I. plattensis among predators tested (P < 0.05). Average daily consumption rates per vertebrate ranged between 0.0 larvae consumed by Iowa darter and 0.49 larvae consumed by brook stickleback (Table 1). Significant predation by brook stickleback prompted additional tests which compared the effects of habitat complexity by adding detritus. There was no significant difference (P = 0.487) between predation rate when larvae were given detritus as a refuge (Table 2).

Across trials conducted with brook stickleback, 53 of 135 (39.25%) larvae were consumed during the 72 h test period; of the 53 larvae consumed, 35 were removed from their cases (66%). The mean case lengths were larger for surviving larvae after the 72 h test period indicating that smaller larvae were consumed, however, this difference in case sizes was not significant (t-test, P = 0.16).

A Spearman rank order correlation was used to determine if there were any significant correlations (P < 0.05) between fish length, larval case length, and the number of larvae consumed. There was a negative correlation (P = -0.345) between the number of larvae consumed after 72 h and fish length, and this correlation was significant (P < 0.05). This indicates fish length and number consumed are not related. Size of fish does not determine how many larvae were consumed for this test.

Among the vertebrate species that consumed greater than a single larva over the 72 h test period, brook stickleback, fathead minnow, and black bullhead displayed considerable aptitude for consuming cased larvae. Each fed on 50% of their total larvae consumed within the first 24 h of the experiment. Western mosquitofish and Plains topminnow consumed the majority of the larvae offered during the final 24 h segment (Fig. 1).

Table 1.

Total number of Ironoquia plattensis larvae consumed by each predator species tested.


Table 2.

Total number of Ironoquia plattensis larvae consumed by brook stickleback, Culaea inconstans, (n = 15 per condition) in aquaria with leaf detritus as refuge for larvae and without leaf detritus.



An artificial scenario was used to evaluate the potential effects vertebrate predators may have on early I. plattensis larvae. This test provided no alternative prey items, no substrate in most trials, and no additional food for 72 h. All predators tested consumed at least one I. plattensis larva with the exception of the Iowa darter, E. exile. Iowa darters have been documented in all major Nebraska river systems since 1894 (Meek 1894), and a study conducted on their diet habits found them to primarily consume copepods and cladocerans (Balesic 1971).

Fig. 1.

Percent of total Ironoquia plattensis larvae consumed over the 72 h test period for each vertebrate species tested.


Several predators used in this experiment have been documented consuming trichopteran larvae in previous studies, including black bullhead (Leunda et al. 2008), green sunfish (Mancini et al., 1979), and fathead minnow (Duffy 1998). Black bullheads utilize most freshwater habitats including slow moving lotic systems (Leunda et al. 2008). Dietary analysis conducted by Leunda et al. (2008) classified them as generalists that exhibit benthophagous feeding behavior. Dominant components of their diet included microcrustaceans, caddisfly larvae, and Oligochaeta in lotic systems. Every larvae consumed by a black bullhead in our study was ingested with its case. Members of the leptocerid caddisfly genus Nectopsyche, which builds a composite case from leaf and mineral material (Wiggins 1996), have been extracted intact from the stomachs of several predatory fish (e.g., channel catfish, Ictalurus punctatus Rafinesque) in lentic systems in Nebraska (Cavallaro, personal observation). Green sunfish are described as having the most diverse diet of the Lepomis sunfish species (Minckley 1963), and they are commonly found in all Nebraska river systems (Jones 1963). In addition, they have been a model species for past studies pertaining to macroinvertebrate predation (Mancini et al. 1979; Sih et al. 1990). The black bullhead and green sunfish were observed targeting larger I. plattensis larvae. The mean larval case length measured before and after the black bullhead and green sunfish trials decreased 0.11 cm and 0.22 cm, respectively. I. plattensis larvae achieve their greatest size as aquatic fifth instars, which coincides with their migration to land to aestivate. An increase in the abundance of predators that select for larger prey during the time I. plattensis migrate may exploit the available food source. This could leave populations with low densities vulnerable to stochastic events. Future studies should include larger instars in feeding trials.

The only cyprinid species tested, fathead minnow, are widespread in Nebraska as a result of their popularity as a bait fish. Sampling conducted by Lynch & Roh (1996) found them to be most abundant when pools of backwater areas were available. Fatheads have been documented consuming zooplankton, mayfly (Ephemeroptera) larvae, caddisfly (Trichoptera) larvae, and chironomid midge larvae with zooplankton being the largest component of their invertebrate diet (Held & Peterka 1974; Duffy 1998). However, low predation rates on I. plattensis were observed during this study.

Among species tested, I. plattensis appears to face potentially high predation rates from brook stickleback during the early aquatic phase of its lifecycle. Our trials were conducted at 10 ºC based on seasonal temperatures when these predators would encounter 2nd and 3rd instars. Brook stickleback have been found to alter both pelagic and benthic invertebrate communities. Hornung & Foote (2006) documented brook stickleback to have a direct negative effect on macroinvertebrate biomass in 24 wetlands in the Western Boreal Forest in Canada. Predation mostly affected early larval stages of invertebrates, resulting in depletion of potential prey for predaceous invertebrates; causing the biomass of predaceous invertebrates to decrease (Hornung & Foote 2006). Miler et al. (2008) reported brook stickleback predation to affect sex ratios in populations of a benthic water moth, Acentria ephemeralla Denis & Schiffermüller (Lepidoptera: Crambidae).

Previous accounts of brook stickleback consuming trichopteran larvae are documented by Stewart et al. (2007), who found trichopteran larvae in stomach samples of brook stickleback diets in the Northwest Territories of Canada in late summer to early autumn. Tompkins & Gee (1983) describe brook stickleback as possessing flexible foraging behavior depending on available prey items based on prey abundance. Observations made during the 72 h test period found brook stickleback persistently targeting the larvae within the case; most of the larvae consumed by brook stickleback were removed from their cases, suggesting gape limitations or inability to digest case material efficiently.

During trials with detritus, the majority of brook stickleback oriented their body sideways appearing to lie down and, burying themselves under the detritus. Degraeve (1970) discussed 3 burrowing behaviors displayed by brook stickleback; during his observations he noted how individuals could submerge and emerge with relative ease from silt substrate and loose detritus but had difficulties manipulating sandy substrates which deterred these behaviors. During their early instars, I. plattensis readily move between detritus and sandy substrates as they develop and construct larger cases (Cavallaro, personal observation).

Different stream substrates and accumulation of leaf litter detritus affect benthic macroinvertebrate community composition as a result of microhabitat availability (Culp & Davies 1985). Stream substrates may be altered by the construction of dams, irrigation canals, and water diversions all of which have occurred in the Platte River system (Eschner et al. 1981). However, in our tests the presence of leaf detritus, in which the caddisflies could burrow, did not increase survival when exposed to brook stickleback (Table 2).

Although brook stickleback are native to eastern Nebraska (Fischer & Paukert 2008), their range appears to have expanded substantially since 1970, and the species is now common throughout the middle Platte River drainage (Chadwick et al. 1997; McAllister et al. 2010). During recent monitoring of known I. plattensis populations, including the type locality, brook stickleback have been captured in low numbers (Cavallaro & Vivian, personal observation). Given the cryptic, benthic nature of brook stickleback and inconsistent fish sampling methods employed, it is unclear whether the species eluded previous documentation at extant I. plattensis sites or has actively dispersed to occupy similar habitats.

Exotic species, including native species that colonize new habitats, have repeatedly been found to cause declines in native fauna. Exotic species with documented effects include G. affinisis (Lawler et al. 1999). Western mosquitofish have reduced abundances of fairy shrimp that are typically found in fishless waters (Leyse et al. 2004). Bence (1988) reported mosquitofish to significantly alter the invertebrate community in study enclosures by reducing microcrustaceans (copepods, cladocera, and ostracods). Among invertebrates, mosquitoes, microcrustaceans and zooplankton have been reported as food sources for mosquitofish (Blanco et al. 2004). Sites with the I. plattensis now contain western mosquitofish, which was introduced to Nebraska from the southeastern United States (Lynch 1988; Haynes 1993). As surface feeders, mosquitofish are considered generalist predators (Lawler et al. 1999), and they have not been reported causing any negative effects on benthic dwelling arthropods.

Literature on benthic macroinvertebrate community structure stresses the importance of habitat complexity (e.g., emergent vegetation, substrate composition, etc.) for cover from predators (Gilinsky 1984). The different time segments of the 72 h test period showed several species, specifically brook stickleback, fathead minnow, and black bullhead, were equipped to consume larvae within the first 24 h (Fig. 1). Most of these species either take shelter in the detritus or have considerably larger gapes relative to the other test species making I. plattensis larvae slightly more at risk. Among the other species tested that consumed greater than a single larvae, Western mosquitofish and Plains topminnow consumed most of the larvae offered within the last 24 h. These species feature a supra-terminal mouth, allowing them to feed on the surface of the water. Benthic in nature, I. plattensis larvae do not appear at risk to these species.

Based on some preliminary results, I. plattensis larvae may be vulnerable to predation at sites where there is a paucity of adequate sandy substrate under detritus. Five of the seven species tested displayed means of predation above the substrate, and brook stickleback consumed larvae in the detritus layer. Adequate cover provides larvae with refuge from predators on top of the slough bed substrate (Culp & Davies 1985). Invasion of temporary waters may sustain fish populations resulting in decreases of I. plattensis, especially in systems where I. plattensis are a large component of the macroinvertebrate community. Changes in the hydrologic cycle that increase the permanency of water in I. plattensis habitat may contribute to a decrease in population size. We recommend future conservation studies concerned with evaluating the predation threats to specific aquatic macroinvertebrate species should explicitly use various benthic substrates in the experimental design.


We would like to thank the University of Nebraska at Kearney Student Research Services Council and the University of Nebraska at Kearney Department of Biology for providing funding for this research. In addition, we extend our thanks to David Schumann for his assistance in the field collecting fish and larvae to conduct these experiments. Current addresses: M. Cavallaro, School of Environment and Sustainability, University of Saskatchewan, 117 Science Place, Saskatoon, Saskatchewan S7N 5C8 Canada,; W. Wyatt Hoback, Dept. of Entomology and Plant Pathology, 127 Noble Research Center, Oklahoma State University, Stillwater, OK 74074-3033, USA;; and L. Vivian, California Department of Transportation, 111 Grand Avenue, MS: 8E Oakland, CA 94612 USA,

References Cited


KD Alexander , MR Whiles . 2000. A new species of Ironoquia (Trichoptera: Limnephilidae) from an intermittent slough of the central Nebraska Platte River, Nebraska. Entomology News 111(1): 1–7. Google Scholar


H Balesic . 1971. Comparative ecology of four species of darters (Etheostomatinae) in Lake Dauphin and its tributary, the Valley River. Master's Thesis, University of Manitoba. Google Scholar


DP Batzer , SA Wissinger . 1996. Ecology of insect communities in non-tidal wetlands. Annual Review of Entomology 41: 75–100. Google Scholar


JR Bence . 1988. Indirect effects and biological control of mosquitoes by mosquitofish. Journal of Applied Ecology 25: 505–521. Google Scholar


S Blanco , S Romo , M Villena . 2004. Experimental study on the diet of mosquitofish (Gambusia holbrooki) under different ecological conditions in a shallow lake. International Review of Hydrobiology 89(3): 250–262. Google Scholar


JW Chadwick , SP Canton , DJ Conklin , PL Winkle . 1997. Fish species composition in the central Platte River, Nebraska. The Southwestern Naturalist 42(3): 279–289. Google Scholar


P Chapman , K Warburton . 2006. Postflood movements and population connectivity in Gambusia (Gambusia holbrooki). Ecology of Freshwater Fish 15: 357–365. Google Scholar


JM Culp , RW Davies . 1985. Responses of benthic macroinvertebrate species to manipulation of interstitial detritus in Carnation Creek, British Columbia. Canadian Journal of Fisheries and Aquatic Sciences 42(1): 139–146. Google Scholar


GM Degraeve . 1970. Three types of burrowing behavior of the brook stickleback, Culaea inconstans. Transactions of the American Fisheries Society 99(2): 433. Google Scholar


WK Dodds , K Gido , MR Whiles , KM Fritz , J Matthews . 2004. Life on the edge: the ecology of Great Plains prairie streams. BioScience 54(3): 205–216. Google Scholar


WG Duffy . 1998. Population dynamics, production, and prey consumption of fathead minnows (Pimephales promelas) in prairie wetlands: a bioenergetics approach. Canadian Journal of Fisheries and Aquatic Sciences 54: 15–27. Google Scholar


T Eschner , R Hadley , K Crowley . 1981. Hydrologic and morphologic changes in the Platte River basin: an historical perspective. USGS, Washington, D.C. Google Scholar


JR Fischer , CP Paukert . 2008. Historical and current environmental influences on an endemic Great Plains fish. The American Midland Naturalist 159(2): 364–377. Google Scholar


B Goldowitz . 2004. Survey for the Platte River caddisfly (Ironoquia plattensis) in Nebraska. Final report. Nebraska Game and Parks Commission, Lincoln, Nebraska. Google Scholar


E Gilinsky . 1984. The role of fish predation and spatial heterogeneity in determining benthic community structure. Ecology 65(2): 455–468. Google Scholar


JL Haynes . 1993. Annual reestablishment of mosquitofish populations in Nebraska. Copeia 1: 232–235. Google Scholar


JW Held , JJ Peterka . 1974. Age, growth, and food habits of the fathead minnow, Pimephales promelas, in North Dakota saline lakes. Transactions of the American Fisheries Society 103: 743–756. Google Scholar


SW Hodges , DD Magoulick . 2011. Refuge habitats for fishes during seasonal drying in an intermittent stream: movement, survival and abundance of three minnow species. Aquatic Sciences 73: 513–522. Google Scholar


JP Hornung , AL Foote . 2006. Aquatic invertebrate responses to fish presence and vegetation complexity in western boreal wetlands, with implications for waterbird productivity. Wetlands 26(1): 1–12. Google Scholar


DJ Jones . 1963. A History of Nebraska's Fishery Resources. Nebraska Game and Parks Commission Publication, Paper 31. Nebraska Game and Parks Commission, Lincoln, Nebraska. Google Scholar


SP Lawler , D Dritz , T Strange , M Holyoak . 1999. Effects of introduced mosquitofish and bullfrogs on the threatened California red-legged frog. Conservation Biology 13(3): 613–622. Google Scholar


PM Leunda , J Oscoz , B Elvira , A Agorreta , S Perea , R Miranda . 2008. Feeding habits of the exotic black bullhead Ameiurus melas (Rafinesque) in the Iberian Peninsula: first evidence of direct predation on native fish species. Journal of Fish Biology 73: 96–114. Google Scholar


KE Leyse , SP Lawler , T Strange . 2004. Effects of an alien fish, Gambusia affinis, on an endemic California fairy shrimp, Linderiella occidentalis: implications for conservation of diversity in fishless waters. Biological Conservation 118: 57–65. Google Scholar


JD Lynch . 1988. Habitat utilization by an introduced fish, Gambusia affinis, in Nebraska (Actinopterygii: Poeciliidae). Transactions of the Nebraska Academy of Sciences and Affiliated Societies 16: 63–67. Google Scholar


JD Lynch , BR Roh . 1996. An ichthyological survey of the forks of the Platte River in western Nebraska. Transactions of the Nebraska Academy of Sciences and Affiliated Societies 23: 65–84. Google Scholar


ER Mancini , M Budosh , BD Steele . 1979. Utilization of autochthonous macroinvertebrate drift by a pool fish community in a woodland stream. Hydrobiologia 62: 249–256. Google Scholar


CT McAllister , VA Virgilio , K Charron . 2010. Two new geographic distribution records for the brook stickleback, Culaea inconstans (Gastrosteiformes: Gastrosteidae), in northwestern Nebraska. The American Midland Naturalist 163(2): 473–475. Google Scholar


SE Meek . 1894. Notes on the fishes of western Iowa and eastern Nebraska. Bullen of the U. S. Fish Commission 133–138 pp. Google Scholar


OM Miler , M Korn , D Straile . 2008. Experimental evidence for a strong influence of stickleback predation on the population dynamics and sex ratio of an aquatic moth. Fundamental and Applied Limnology 173(3): 187–196. Google Scholar


WL Minckley . 1963. The ecology of a spring stream, Doe Run, Meade Co., Kentucky. Wildlife Monographs 11: 1–124. Google Scholar


WA Sheaffer , JG Nickum . 1986. Backwater areas as nursery habitats for fishes in pool 13 of the upper Mississippi River. Hydrobiologia 36(1): 131–139. Google Scholar


A Sih , J Krupa , S Travers . 1990. An experimental study on the effects of predation risk and feeding regime on the mating behavior of the water strider. The American Midland Naturalist 135(2): 284–290. Google Scholar


DB Stewart , TJ Carmichael , CD Sawatzky , NJ Mochnacz , JD Reist . 2007. (Culaea inconstans). Canadian Journal of Fisheries and Aquatic Sciences 2798:1–16. Google Scholar


AM Tompkins , JH Gee . 1983. Foraging behavior of brook stickleback, Culaea inconstans (Kirtland): optimization of time, space, and diet. Canadian Journal of Zoology 61: 2482–2490. Google Scholar


United States Fish and Wildlife Service. 2012. Federal Register 77(169): 52650–52673. Google Scholar


LA Vivian . 2010. Updates on the distribution and population status of the Platte River caddisfly, Ironoquia plattensis, and an assessment of threats to its survival. Master's Thesis, University of Nebraska at Kearney. Google Scholar


LA Vivian , MC Cavallaro , K Kneeland , WW Hoback , KM Farnsworth-Hoback , JE Foster . 2013. Current known range of the Platte River caddisfly, Ironoquia plattensis, and genetic variability among populations from three Nebraska Rivers. Journal of Insect Conservation 17: 885–895. Google Scholar


GA Wellborn , DK Skelly , EE Werner . 1996. Mechanisms creating community structure across a freshwater habitat gradient. Annual Review of Ecology and Systematics 27: 337–363. Google Scholar


MR Whiles , BG Goldowitz , RE Charlton . 1999. Life history and production of a semi-terrestrial limnephilid caddisfly in an intermittent Platte River wetland. Journal of the North American Benthological Society 18(4): 533–544. Google Scholar


MR Whiles , B Goldowitz . 2005. Macroinvertebrate communities in central Platte River wetlands: patterns across a hydrologic gradient. Wetlands 25: 462–472. Google Scholar


GB Wiggins . 1996. Larvae of the North American caddisfly genera (Trichoptera) 2nd edition. University of Toronto Press, Toronto, Canada. 457 pp. Google Scholar


DD Williams , NE Williams . 1975. A contribution to the biology of Ironquia punctatissima (Trichoptera: Limnephilidae). Canadian Entomologist 107: 829–832. Google Scholar


SA Wissinger , HH Whiteman , GB Sparks , GL Rouse , WS Brown . 1999. Tradeoffs between competitive superiority and vulnerability to predation in caddisflies along a permanence gradient in subalpine wetlands. Ecology 80: 2102–2116  Google Scholar
Michael C. Cavallaro, Lindsay A. Vivian, and W. Wyatt Hoback "Aquatic Vertebrate Predation Threats to the Platte River Caddisfly (Trichoptera: Limnephilidae)," Florida Entomologist 98(1), 152-156, (1 March 2015).
Published: 1 March 2015
benthic macroinvertebrate
brook stickleback
comportamiento de pez espinoso del arroyo
conservación de invertebrados
fish behavior
invertebrate conservation
macroinvertebrados bentónicos
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