Research Interests

Research Interests

Trent’s research focuses on population- and community-level interactions involving freshwater fishes in both lotic and lentic ecosystems. The objective of his research program is to develop a greater understanding of the role of biotic and abiotic factors on the population ecology and biology of fishes and community structure of aquatic ecosystems in order to assist subsequent natural resource conservation and management efforts. Trent’s current research is focused in three distinct areas: (1) population ecology and conservation of fishes in the Great Lakes basin; (2) ecology and biology of fish populations and communities in large river ecosystems; and (3) impacts of human-induced perturbations on aquatic community structure and function. Examples of Trent’s research in these particular areas are outlined below.

Population Ecology and Conservation of Fishes in the Great Lakes Basin

Throughout the Great Lakes, many native fish species are imperiled due to habitat degradation, overexploitation, and/or the introduction of exotic organisms. To further complicate matters, little is known about the population dynamics, stock structure, and habitat requirements for many of these fishes. As a consequence, restoration of native species complexes and subsequent management efforts cannot proceed until more is known regarding basic population-level processes associated with these species. Since coming to Purdue University, Trent has initiated a research program focusing on the population ecology of following three Great Lakes fishes: lake sturgeon, lake herring, and lake whitefish.

Lake Sturgeon

Characterization of Early Life History Stages

In the Green Bay basin, an insufficient understanding of lake sturgeon early life history and loss of important nursery habitats has been identified as a critical impediment to successful rehabilitation of this species. Because each life stage has unique resource requirements, identifying and preserving critical microhabitats which provide sufficient prey resources and a suitable physico-chemical environment will be important determinants of successful recruitment. This study examined linkages among population abundance and structure, distribution, and movement and usage patterns of larval, juvenile, and subadult lake sturgeon relative to the availability of physical habitat, chemical environmental factors, and benthic macroinvertebrate prey in the lower Peshtigo River and the immediate, nearshore waters of Green Bay. Sampling results from this project will also be used to establish a quantitative sampling protocol for standardizing assessment surveys of early life stages of lake sturgeon in Great Lakes waters. Age-0 lake sturgeon (mean fork length = 239 mm [range, 223 to 249 mm]; mean weight = 83 g [range, 74 to 90 g] were captured from September through October 2002 in the lower section of the Peshtigo River, Wisconsin, using wading surveys with dip nets, haul seines, backpack electrofishing, snorkeling, set lines, bottom trawls, gill nets, and fyke nets. All fish were measured and weighed, and water quality parameters (i.e. water temperature, dissolved oxygen, pH, and conductivity), water depth, and river velocity were measured at each collection location. Radio transmitters were attached to juvenile lake sturgeon larger than 75 g in weight, and were tracked at least twice each day. At each capture site, a bottom dredge sample was also collected. Dominant substrate types were visually estimated and a sample was preserved for later analysis of macroinvertebrate assemblage. Quantitative analysis of habitat types within the Peshtigo River was conducted using dredge samples collected at three points perpendicular to river flow at 50-m intervals. All juvenile lake sturgeon were captured over sand substrates, with particle size ranging from 1.99 to 0.12 mm in diameter, in depths less than 1.0-m, velocities greater than 0.66 m/s, and temperatures ranging from 14.5 to 23.8˚C. Eight of thirteen juvenile lake sturgeon were collected over substrate containing macroinvertebrates. Those with transmitters (N = 4) did not leave their capture site until water temperatures within the river declined to 12°C, when the fish moved downstream and into Green Bay within a two- to three-day period. Catch-per-unit-effort (CPUE) was highest with the day seining (CPUE = 2.02 fish/h), followed by day wading surveys and night seining (CPUE = 0.86 and 0.80 fish/h, respectively). No age-0 sturgeon were captured with bottom trawls, set lines, or fyke nets. We recommend the use of day seining or day wading surveys in rivers similar to the Peshtigo River (i.e., shallow and low turbidity) for capturing age-0 lake sturgeon.

Funding Source: Great Lakes Fishery Trust

Personnel: Angela Benson (completed master’s thesis in August 2004)

Publications:

· Benson, A. C., T. M. Sutton, R. F. Elliott, and T. G. Meronek. 2006. Biological attributes of age-0 lake sturgeon in the lower Peshtigo River, Wisconsin. Journal of Applied Ichthyology (in press).

· Benson, A. C., T. M. Sutton, R. F. Elliott, and T. G. Meronek. 2005. Movement patterns and habitat preferences of age-0 juvenile lake sturgeon in the lower Peshtigo River, Wisconsin. Transactions of the American Fisheries Society 134:1400-1409.

· Benson, A. C., T. M. Sutton, R. F. Elliott, and T. G. Meronek. 2005. Evaluation of sampling techniques for age-0 juvenile lake sturgeon in the lower Peshtigo River, Wisconsin, and nearshore waters of Green Bay. North American Journal of Fisheries Management 25:1378-1385.

· Sutton, T. M., and A. C. Benson. 2003. Influence of external radio transmitter size and shape on survival, growth, and tag loss of juvenile lake sturgeon. Transactions of the American Fisheries Society 132:1257-1263.

Collaborators: Robert Elliott, Thomas Meronek, and Gregory Kornely

Assessment of Remnant Population Status

There is a fundamental and critical lack of knowledge regarding the size, status, and stock characteristics of most remnant populations of lake sturgeon currently inhabiting the Lake Michigan basin. As a result, this lack of understanding has hindered efforts to rehabilitate lake sturgeon throughout the watershed, a commitment identified in existing rehabilitation and management plans for this species. To address this need, a basin-wide study has been implemented that will involve cooperative research efforts among five natural resources management agencies (U.S. Fish and Wildlife Service, Wisconsin and Michigan Departments of Natural Resources, Little Traverse Bay Band of Odawa Indians, Little River Band of Ottawa Indians) and five public universities (Purdue, Michigan State, Central Michigan, and Michigan Technological Universities, and the University of Georgia) to comprehensively assess and characterize the most significant remnant lake sturgeon stocks that persist and spawn in tributaries of Lake Michigan and Green Bay. Specifically, the Purdue University component of this study will examine population abundance and reproductive success of spawning adults, describe spawner habitat use and availability of spawning and resident lake sturgeon in the St. Joseph and Kalamazoo Rivers, tributaries in southeastern Lake Michigan, and sample for early life stages (i.e., eggs, larvae, and juveniles) in order the characterize spawning, recruitment success, and nursery habitat availability.

Funding Source: Great Lakes Fishery Trust, Purdue University Department of Forestry and Natural Resources

Personnel: Daniel Daugherty, Rebecca Zeiber, and Stephanie Shaw (Project completed in August 2005)

Publications:

· Zeiber, R. A., S. M. Shaw, and T. M. Sutton. 2006. Assessment of remnant lake sturgeon populations and habitat availability in the lower and upper Kalamazoo River, Michigan. Great Lakes Fishery Trust, Lansing, Michigan.

Collaborators: Robert Elliott, Kim Scribner, Edward Baker, Nancy Auer, Douglas Peterson, Thomas Meronek, Gregory Kornely, Marty Holtgren, Tracy Galarowicz, Terrence Lychwick, Steve Lenart, and Kregg Smith

Potential for Habitat Rehabilitation in Lake Michigan Tributaries

Lake sturgeon Acipenser fulvescens were historically one of the most numerous fish species in the main basin of Lake Michigan and Green Bay. Throughout the Great Lakes, lake sturgeon abundance declined dramatically during the 1800s, with populations reduced to remnant levels by the early 1900s. Factors attributed to these declines include water pollution, physical habitat alterations, impediments to migration, and commercial overexploitation. Although improvements in water quality and harvest reductions have allowed for some recovery, limited availability of staging, spawning, and nursery habitats in historically important tributaries remains an impediment to rehabilitation. Many of the rivers that presently support or historically supported lake sturgeon populations have been altered by the construction of hydropower dams, changes in land-use practices, and other anthropogenic impacts. As a result, the extent to which these factors continue to limit habitat availability, and consequently recovery efforts, remains unknown. Enhancement or rehabilitation of degraded habitats, including the addition of proper substrates, creation of backwater areas, maintenance of adequate and natural stream flows, removal of barriers, and installation of fish-passage structures, will be necessary to restore lake sturgeon tributaries throughout the Lake Michigan watershed. Assessment of past and present habitat availability is necessary, and replacement, enhancement, or renewed accessibility to habitats will be essential for successful restoration. Therefore, habitat enhancement or rehabilitation must be a priority for tributaries of Green Bay in order to allow for the long-term sustainability and recovery of lake sturgeon. Specific objectives of this research include: (1) assessment and quantification of lake sturgeon spawning, nursery, and adult habitats currently available and potentially available above existing barriers; (2) examination of spatial (i.e., longitudinal) relationships of lake sturgeon habitats below and above existing barriers; and (3) development of a decision tool for prioritizing Green Bay tributaries, identifying appropriate rehabilitation strategies, and directing future enhancement or restoration of important habitats or habitat features for lake sturgeon populations.

Funding Source: Great Lakes Fishery Trust, U.S. Fish and Wildlife Service, Purdue University Department of Forestry and Natural Resources

Personnel: Daniel Daugherty (current doctoral student)

Publications:

· Project not yet completed; project completion date: December 2006

Collaborators: Robert Elliott, Mark Holey, Edward Baker, and Michael Donofrio

Effects of Mortality Sources on Population Viability

Lampricide applications in streams containing swim-up larvae and small juvenile lake sturgeon Acipenser fulvescens may negatively impact recruitment, rehabilitation, and sustained viability of this species in the Great Lakes. As a result, a no observable effect (i.e., no mortality) treatment protocol has been implemented in streams supporting lake sturgeon. However, the overall effectiveness of lampricide treatments may be diminished because greater numbers of parasitic-phase sea lampreys Petromyzon marinus may be produced from tributaries through inefficient or failed lampricide treatments. We used a stage-structured, life-history model to examine the impacts of lampricide applications and sea lamprey parasitism on the population viability of lake sturgeon in the Laurentian Great Lakes basin. Population abundance, the number of age-1 recruits, and reproductive potential of lake sturgeon exhibited relative percentage decreases with increasing mortality of age-0 juvenile fish (range, 0 to 100%) as a result of lampricide applications at four-year treatment intervals. When larval sea lamprey mortality (range, 100 to 0%) following lampricide treatments was incrementally decreased, lake sturgeon mortality from increased sea lamprey parasitism for both the low and high mortality simulation scenarios resulted in relative percentage decreases in population abundance, the number of age-1 recruits, and reproductive potential from baseline conditions. Incremental increases in sea lamprey-induced lake sturgeon mortality (range, 0 to 22%) as estimated from wounding rate data resulted in relative percentage decreases in population abundance, the number of age-1 recruits, and reproductive potential from baseline conditions. Based on the results of our model simulations, it appears that mortality agents, such as sea lamprey parasitism, that influence subadult and adult lake sturgeon have a greater impact on the long-term population viability of this species than mortality factors that affect early life stages (i.e., lampricide applications). As a result, we do not recommend that lampricide-application strategies for the control of larval sea lamprey populations in tributaries containing lake sturgeon continue to follow the no effect protocol in order to allow for the long-term rehabilitation and management for this species.

Funding Source: Great Lakes Fishery Commission

Personnel: Trent Sutton and Rebecca Zeiber

Publications:

· Sutton, T. M., B. L. Johnson, T. D. Bills, and C. S. Kolar. 2004. Effects of sea lamprey induced mortality sources on lake sturgeon population viability: an ecological modeling approach. Great Lakes Fishery Commission Technical Report, Ann Arbor, Michigan.

Collaborators: Barry Johnson, Cynthia Kolar, and Terry Bills

Host-Size Selection and Lethality of Sea Lamprey on Lake Sturgeon

The use of the no observable effect (i.e., no mortality) lampricide treatment protocol to protect lake sturgeon Acipenser fulvescens populations might also increase production of sea lampreys Petromyzon marinus and, consequently, parasitism on lake sturgeon. However, no studies have examined the influence of sea lamprey parasitism on lake sturgeon survival. Because previous model simulations indicate that sea lamprey attacks on adult lake sturgeon adversely affect long-term population viability, understanding is needed of the relations among wounding rate, wound type, and host survival to ensure that sea lamprey control strategies optimize lake sturgeon rehabilitation in the Great Lakes. For this study, we will examine the following objectives: (1) compare the short- and long-term survival of three size groups of lake sturgeon after a single sea lamprey attack; (2) determine the rate of wound healing and scar retention of lake sturgeon hosts following sea lamprey attacks; (3) develop a classification system for the categorization of sea lamprey marks on lake sturgeon. For this experiment, we will use three size classes of lake sturgeon (N = 25 fish per size class; 125 lake sturgeon for this study are currently at Purdue University): (1) small (400 to 599 mm fork length); (2) medium (600 to 799 mm); and (3) large (800 to 999 mm). Each lake sturgeon will be weighed, individually placed in a holding tank with a single, pre-weighed sea lamprey, and the time and location of attachment will be recorded for each pairing. Following detachment, both fish will be re-weighed and the wound type on each lake sturgeon will be classified according to standard criteria. Surviving lake sturgeon will be transferred to recovery tanks at the same temperature as the test tanks to determine delayed mortality during a 14- to 21-d recovery period. Any mortality during this period will be further classified into fish that died from sea lamprey attack or secondary infection. Survivors will be held an additional 60+ days at 10^oC to determine the rate of wound healing and scar retention. The number of live and dead lake sturgeon will be examined by size class, and location and duration of sea lamprey attachment. Dead lake sturgeon will also be assessed based on the source and timing of mortality. Sea lamprey data will be examined by weight gain, and location and duration of attachment.

Funding Source: Great Lakes Fishery Commission

Personnel: Holly Patrick (current master’s student)

Publications:

· Project not yet completed; project completion date: December 2006

Collaborators: William Swink and Anant Bharadwaj

Mortality and Recruitment Mechanisms of Lake Sturgeon Early Life Stages

Identification of the factors that regulate fish populations has been a major goal of fisheries research because variable survival among early life stages determines overall viability of the species. Because each life stage has unique requirements, identification and quantification of egg, larval, and juvenile losses is required to understand the criteria for successful survival and recruitment to subsequent life stages. However, the extent to which mortality mechanisms impact lake sturgeon early life stages and limit recovery efforts remain unknown. For rehabilitation to be successful, an understanding of the relationship among mortality and recruitment factors acting on lake sturgeon populations is necessary. For this study, we will examine the following objectives: (1) estimate egg density, production of larvae during the drift period, and the abundance of age-0 juvenile lake sturgeon prior to river emigration in the lower Peshtigo River; (2) identify and quantify the mechanisms of mortality during each lake sturgeon life stage; (3) determine if predation on age-0 life stages is dependent upon lake sturgeon body size; and (4) assess how mortality sources influence recruitment dynamics, year-class strength, and population viability of lake sturgeon. Lake sturgeon egg density will be estimated using substrate mats (May 2006 and 2007). To examine predation on eggs and yolk-sac larvae, we will use in-situ exclosures constructed of plastic boxes filled with coarse substrates. To estimate relative abundance and production of lake sturgeon swim-up larvae, fish will be collected using drift nets set below the Peshtigo River spawning area (May and June 2006 and 2007). Relative and absolute abundance of juveniles will be estimated from fish collected and marked or tagged following wading capture surveys (June - November 2006 and 2007). Fish predators will be collected using gill nets and electrofishing (May - November 2006 and 2007). This research will directly increase our understanding of the mechanisms directing recruitment dynamics of lake sturgeon in the Lake Michigan basin and help to identify mortality sources that may negatively impact ongoing and future recovery efforts for this species throughout the Great Lakes basin.

Funding Source: Great Lakes Fishery Trust

Personnel: David Caroffino (current doctoral student)

Publications:

· Project not yet completed; project completion date: May 2009

Collaborators: Robert Elliott, Edward Baker, and Michael Donofrio

Lake Herring

Since declining in the 1960s, lake herring Coregonus artedi populations have remained suppressed throughout Lake Superior, and only one strong year class (1998) has occurred over the past decade. During this time, lake herring populations in Lake Superior have also exhibited high recruitment variability. To improve our understanding of the mechanisms which influence year-class strength, we conducted a 225-d laboratory experiment to evaluate the effects of body size, condition, energy stores, and food ration on overwinter survival of age-0 lake herring. Small (total-length range, 60 to 85 mm) and large (total-length range, 85 to 110 mm) fish were maintained under thermal and photoperiod regimes that mimicked those in Lake Superior from October through May. Fish in each size class were maintained at two feeding treatments: Artemia ad libitum or no food. Mortality of large lake herring (fed, 3.8%; starved, 20.1%) was significantly less than those of small fish (fed, 11.7%; starved, 32.0%) within feeding treatments. Body condition and crude lipid content declined over the experiment for all fish; however, index values were significantly greater for large and small fed fish than large and small starved individuals. Final crude protein and gross energy content was also significantly greater in large fed lake herring (17.6% and 1,966 cal/g, respectively) followed by small fed (17.1% and 1,497 cal/g, respectively), large starved (15.4% and 1,125 cal/g, respectively), and small starved (13.2% and 799 cal/g, respectively) fish. Individuals that survived the winter period had significantly greater energy stores than fish that died during the study. These results suggest that depletion of energy stores contributes to greater winter mortality of small fish, and may partially explain the recruitment variability that has been observed for lake herring in Lake Superior.

Funding Source: Michigan Sea Grant College Program, Purdue University Department of Forestry and Natural Resources

Personnel: Kevin Pangle (completed master’s thesis in July 2003)

Publications:

· Pangle, K. L., T. M. Sutton, R. E. Kinnunen, and M. H. Hoff. 2005. Effects of body size, condition, and lipid content on the survival of juvenile lake herring during rapid cooling events. Journal of Great Lakes Research 31:360-366.

· Pangle, K. L., and T. M. Sutton. 2005. Temporal changes in the relationship between body condition and proximate composition of juvenile lake herring. Journal of Fish Biology 66:1-13.

· Pangle, K. L., T. M. Sutton, R. E. Kinnunen, and M. H. Hoff. 2004. Overwinter survival of age-0 lake herring in relation to body size, physiological condition, energy stores, and food ration. Transactions of the American Fisheries Society 133:1224-1234.

· Pangle, K. L. T. M. Sutton, and P. B. Brown. 2003. Evaluation of practical and natural diets for juvenile lake herring. North American Journal of Aquaculture 65:91-98.

Collaborators: Ronald Kinnunen and Michael Hoff

Lake Whitefish

Lake whitefish Coregonus clupeaformis historically supported an important commercial fishery in the Great Lakes. In Lake Michigan, this species formed the basis of the commercial fishery since the 1970s, with peak harvest occurring in the early 1990s. However, annual yield, length- and weight-at-age, and body condition of lake whitefish have all declined dramatically since this time. These declines have been largely attributed to the invasion of zebra mussel Dreissena polymorpha, which appears to have contributed to the lake-wide decrease and disappearance of the benthic amphipod Diporeia, the primary prey of whitefish. Egg lipid and caloric content, size-at-hatching, and subsequent growth and survival are known to be positively related for lake whitefish. Therefore, declines in Diporeia, a prey source with a higher energy content and essential omega-3 fatty-acid (FA) concentrations than many other prey types, may adversely impact recruitment because females are likely to produce smaller eggs with lower quality. Consequently, lake whitefish will hatch at smaller sizes, predisposed to essential fatty-acid deficiency, which may translate to lower first-year survival due to limited feeding opportunities and greater predation mortality. Because fall body size is strongly coupled to summer growth, smaller age-0 fish typically accumulate less energy reserves prior to the end of the growing season, more rapidly exhaust these stores over the winter, and are more likely to suffer mortality during this period. This research will contribute to our understanding of trophic food-web impacts on recruitment dynamics of lake whitefish in Lake Michigan and provide critical information necessary for improving fishery yield forecasts. The primary objective of this project is to determine the role and relationship of body size, condition, and proximate composition (i.e., lipid, protein, carbohydrate, caloric, water, and ash content; fatty-acid composition) on the first-year growth and survival of juvenile whitefish through the first winter of life. An additional objective of this study will be to determine the proximate composition of juvenile whitefish prey. Given the nature and magnitude of the alterations in trophic food-web structure that have taken place in Lake Michigan following the invasion of zebra mussels and the decline in Diporeia, it is imperative that we develop a better understanding of how these changes are affecting the dynamics and health of fish populations, particularly those with significant economic and ecological importance as whitefish. This research will directly contribute to our understanding of the mechanisms directing recruitment dynamics of whitefish in Lake Michigan and help to identify indices of fish health that federal, state, and tribal natural resource management agencies can use to monitor first-year growth, survival, and natural mortality of juvenile whitefish.

Funding Source: Great Lakes Fishery Trust, Purdue Research Foundation

Personnel: Andrew Muir (current doctoral student)

Publications:

· Project not yet completed; project completion date: October 2007

Collaborators: Ronald Kinnunen, Mark Ebener, Michael Arts, Marten Koops, John Fitzsimons, Thomas Johnston, Randall Claramunt, Timothy Johnson, and Robert Montgomerie

Brook Trout

The successful restoration of native brook trout Salvelinus fontinalis populations in Lake Superior depends on an understanding of the phenotypic and genetic differences among geographically isolated stocks and the successful rearing of locally adapted populations in the hatchery environment. We propose to quantify developmental, morphological, and physiological characteristics among brook trout strains exhibiting variable migratory and non-migratory life history types, using both traditional and enhanced rearing environments. We hypothesize that significant differences exist among brook trout populations with variable life history strategies, and that strains will perform differently between traditional and enhanced rearing environments. To test our hypotheses, we will: 1) compare developmental, physiological, and morphological characteristics among brook trout stocks from Lake Superior in two different rearing environments, and 2) evaluate differences in these characteristics within stocks reared in either a traditional or enhanced rearing environment. Brook trout strains (having both migratory and non-migratory ancestries) currently or historically used in Lake Superior drainage stocking and rehabilitation efforts will be used for this study. Fish from each of five brook trout populations (Siskiwit, Tobin Harbor, Jumbo River, Nipigon, Iron River) will be used for this laboratory experiment. Treatments will exist of five tanks with traditional rearing (no substrate or cover, broadcast feeding) and five tanks with enhanced rearing (providing substrate, cover, and underwater feeding), each strain experiencing both treatment types. After six months of growth, individuals will be PIT-tagged, weighed, standard length measured, and a photo taken for body morphology and coloration (silver index) measurements. These same data and photos will be taken every six months through age 2, and individual growth rates calculated for each interval. We will examine differences among strains and among families within strains for time to hatch, and including tests for rearing environment, and rearing environment by strain effects for morphology, coloration (silver index), and growth. In addition, we will also examine the effect of rearing environment on social dominance, survival, growth, and condition in the presence and absence of mutual competition from conspecifics reared in the alternative rearing environment (i.e., enriched versus traditional rearing environment for each strain). These attributes for each strain of fish reared in the enriched environment will also be examined in the presence of fish from each of the other strains separately (i.e., Nipigon versus Siskiwit, Nipigon versus Jumbo, Nipigon versus Iron Riever, etc.) to determine differential suitability among stocks for rehabilitation stocking efforts in Great Lakes tributaries.

Funding Source: Purdue University

Personnel: Lorena Edenfield (current master’s student)

Publications:

· Project not yet completed; project completion date: August 2008

Collaborators: Krista Nichols and Dale Bast

Ecology and Biology of Fish Populations and Communities in Large River Ecosystems

Large natural floodplain rivers are among the most biologically productive and diverse aquatic ecosystems. Fish communities are an integral component of these freshwater ecosystems as they perform vital fundamental services for maintaining ecosystem function and resilience and also support regionally and economically important fisheries. Because temperate freshwater ecosystems in North America are being depleted of species nearly as rapidly as tropical forests, it is imperative that we fully understand the fish populations that occupy these unique environments. Trent is currently working with state management agencies to meet this particular need, focusing on the following three fishes: shovelnose sturgeon, flathead catfish, and blue sucker.

Shovelnose Sturgeon

Shovelnose sturgeon Scaphirhynchus platorynchus support a commercial fishery throughout much of the Mississippi and Missouri River drainages. There is concern that harvest closures for Eurasian sturgeons may result in increased exploitation of shovelnose sturgeon to meet global demands for caviar. For this study, population attributes of shovelnose sturgeon were examined from an exploited and unexploited reach of the upper Wabash River, Indiana. Fish (N = 4,789) were captured from April 2003 through November 2004 between Wabash and Terre Haute, Indiana, using direct current electrofishing, experimental gill nets, and benthic trawls. Catch-per-unit-effort (CPUE) varied on a temporal basis, with CPUE for the unexploited reach greater than the exploited reach from April through June (range, 5 to 58 fish/hr) while the exploited reach was greater throughout the rest of the year (range, 4 to 12 fish/hr). Catch rates were highest for both reaches from March through May, and approached 500 fish/hr during early May. Fork length (FL) of captured fish ranged from 273 to 858 mm, but few fish < 550 mm were captured. Median FL and wet weight were 683 mm and 1,208 g, respectively (range = 273 to 858 mm and 52 to 3,381 g, respectively). Shovelnose sturgeon ranged from ages 2 to 30, with 95% of the fish between ages 9 and 20. Total annual mortality for fish between ages 13 and 18 was 20%. Empirical growth rates derived from shovelnose sturgeon that were marked and recaptured were slow, with 74% of fish showing negative or no growth in length while at large. Relative weight of shovelnose sturgeon was significantly different among relative stock density (RSD) length categories, with trophy length fish (median = 87) having higher values than preferred and memorable length categories (both, median = 82). Population characteristics of shovelnose sturgeon in the upper Wabash River were within the range reported for other river systems. Although growth and relative weight were low compared to the Mississippi and Missouri Rivers, shovelnose sturgeon in the upper Wabash River attained a larger body size, reached older age classes, experienced lower mortality rates, and higher relative abundance. Results from this study will allow for the detection of shifts in abundance, size and age structure, and gender ratio in response to harvest or natural perturbations more quickly and the development of appropriate management actions to ensure the sustainability of this species and its fishery.

Funding Source: Purdue University College of Agriculture and Department of Forestry and Natural Resources, Indiana Department of Natural Resources, American Fisheries Society

Personnel: Anthony Kennedy (completed master’s degree in December 2005)

Publications:

· Kennedy, A. J., T. M. Sutton, T. C. Stefanavage, and B. E. Fisher. In review. Effects of harvest and length limits on shovelnose sturgeon in the upper Wabash River, Indiana. Journal of Applied Ichthyology.

· Kennedy, A. J., T. M. Sutton, and B. E. Fisher. In review. Population attributes of shovelnose sturgeon in the upper Wabash River, Indiana. North American Journal of Fisheries Management.

· Kennedy, A. J., T. M. Sutton, and B. E. Fisher. 2006. Reproductive biology of female shovelnose sturgeon in the upper Wabash River, Indiana. Journal of Applied Ichthyology (in press).

Collaborators: Brant Fisher, Thomas Stefanavage, Leslie Frankland, and Robert Maher

Flathead Catfish

Flathead catfish have historically gathered little interest from recreational and commercial anglers in the northern United States, resulting in a lack of information regarding the population characteristics, movement patterns, habitat use, and home range of these stocks. The purpose of this study was to examine these characteristics of flathead catfish in the lower St. Joseph River, Michigan, to direct future management efforts and increase our knowledge of flathead catfish in the northern United States. To examine the biological attributes and stock dynamics of flathead catfish in this system, fish were collected from June through September 2002 and 2003 using stationary electrofishing. Fish density was estimated at 191 individuals/rkm (range, 92 to 309 fish/rkm) and annual survival ranged from 67 to 76%. Growth was greatest for fish less than two years of age and decreased among older age classes. The size and age structure of flathead catfish was dominated by fish less than 400-mm TL and four years of age, although individuals greater than 1,100-mm total length and up to age 17 were present in the population. Seasonal movement patterns, habitat use, and home range of flathead catfish were determined using ultrasonic telemetry from June 2002 through August 2003. Habitat use of flathead catfish was dominated by large woody debris and rip-rap at water depths less than 3 m during all seasons except winter, when fish utilized main-channel pool habitats associated with coarse substrates at a mean water depth of 4 m. Flow rates at fish locations were not significantly different among seasons. The seasonal movement distances and home range of flathead catfish were greatest during spring and fall months when fish transitioned between summer and winter habitats. These results suggested that the population characteristics of flathead catfish in this system are similar to those of other stocks throughout their geographic range, and that the rate of exploitation in this system is low. Further, seasonal differences exist in the movement patterns, habitat-use, and home range of flathead catfish, and that the availability of structure and main-channel pool habitats are important considerations in the management of this species.

Funding Source: Purdue University Department of Forestry and Natural Resources, Great Lakes Fishery Trust, and Michigan Department of Natural Resources

Personnel: Daniel Daugherty (completed master’s degree in December 2003)

Publications:

· Daugherty, D. J., and T. M. Sutton. 2005. Effectiveness of a chase boat for electrofishing flathead catfish in the lower St. Joseph River, Michigan. North American Journal of Fisheries Management 25:1528-1532.

· Daugherty, D. J., and T. M. Sutton. 2005. Diel movement patterns and habitat use of flathead catfish in the lower St. Joseph River, Michigan. Journal of Freshwater Ecology 20:1-8.

· Daugherty, D. J., and T. M. Sutton. 2005. Seasonal movement patterns and habitat use of flathead catfish in the lower St. Joseph River, Michigan. North American Journal of Fisheries Management 25:256-269.

· Daugherty, D. J., and T. M. Sutton. 2005. Population abundance and stock characteristics of flathead catfish in the lower St. Joseph River, Michigan. Transactions of the American Fisheries Society 25:1191-1201.

Collaborators: Jay Wesley and James Dexter

Blue Sucker

The blue sucker Cycleptus elongates is an important species in freshwater ecosystems because it provides an important prey base for top predators. Although no longer listed as a species of special concern in Indiana (delisted in 2004), blue suckers are considered threatened or endangered across most of their native range of the Mississippi and Rio Grande River basins. The objectives of this study were to describe the age and growth characteristics of blue sucker in the upper Wabash River, Indiana. Blue suckers (N = 209) were collected using boat electrofishing from June 2003 to April 2005. Physical structures, which included dorsal and pectoral rays, scales, otoliths, and opercles, were removed for age estimation. The mean total length of sampled fish was 610 mm (range, 454 to 739 mm) and 2,075 g wet weight (range, 779 to 4,298 g). The mean age of the population sampled was 5.5 years (range, 3 to 10 years). Log-transformed wet weight (W) and total length (TL) data were used in an ordinary least-squares regression to develop a relationship of log₁₀W = 3.3726 × log₁₀TL - 6.0912. Mean relative condition was 100.6 (range, 66.2 to 141.0), and no length-dependent trends in this index were detected. Length-at-age and precision between age estimates among structure’s analysis is ongoing. The results of this study suggest that the blue sucker population in the upper Wabash River is comprised of individuals with good relative condition with a broad size and age structure range.

Funding Source: Purdue University College of Agriculture

Personnel: Thomas Bacula

Publications:

· Project not yet completed; projected completion date: December 2005

Collaborators: Brant Fisher, Leslie Frankland, and Daniel Daugherty

Impacts of Human-Induced Perturbations on Aquatic Community Structure and Function

While the ecology and management of riparian zones has been well studied in the American southwest and Pacific Coast of North America, the same cannot be said of the eastern corn-belt region or boreal mixed-wood forests. Although unharvested forest strips are often left along permanent streams to protect riparian habitat, the width of these reserves is typically inadequate to mitigate the effects of surrounding land-use practices. Because riparian zones provide important habitat features for aquatic organisms, understanding how human encroachment of riparian areas influences the structure and function of aquatic communities is an important undertaking. Further, developing an understanding of how the intentional introductions of non-native fishes can disrupt energy flow, trophic dynamics, and biotic interactions is also critical for understanding aquatic community structure and function. Trent has initiated research on the effects of land-use practices and riparian zone structure in small warm-water streams in the upper Wabash River drainage of Indiana and coolwater streams in the boreal forests along the Canadian Shield of northern Ontario. Further, he has begun new research on the impacts of western mosquitofish on native fish and amphibian assemblages in lotic and lentic waters of Indiana.

Agriculture-Dominated Streams of the Upper Wabash River

Using the National Water-Quality Assessment (NAQWA) developed by the U.S. Geological Survey, we conducted an examination of the physical (i.e., in-stream and riparian habitat, channel conditions, and hydrology), chemical (i.e., dissolved gases, ions, and nutrients), and ecological (i.e., fish, benthic macroinvertebrates, and algal communities) components as part of an integrated assessment to determine the status and trends in water quality of wadeable lotic systems within the upper Wabash River basin. By developing an understanding of the major natural and anthropogenic factors that affect observed water-quality conditions and trends in this drainage, we will be able to provide private landowners and natural resource planning agencies with the information necessary to not only effectively manage aquatic ecosystems, but to develop and implement land-use strategies that are consistent with sound stewardship practices across terrestrial-aquatic boundaries. This implementation framework will be enhanced by the development of an empirical relationship among habitat availability, water quality, and biological condition at regional and local scales that will allow for the development and use of an integrated ecosystem model to forecast changes in environmental conditions given alternative approaches for maintenance or rehabilitation efforts within the upper Wabash River basin. Specific study objectives of this project include: (1) development of relationships among fish community structure, benthic macroinvertebrate community structure, algal community structure, physical habitat complexity, and water chemistry under varying environmental gradients; (2) examination of local natural and human land-use patterns and practices on the relationship between biological, physical, and chemical components of the aquatic ecosystem; (3) determination of the influence of regional and segment characteristics and dynamics of the basin on the relationship between biological, physical, and chemical components of the aquatic ecosystem; and (4) development of a framework for bioassessment that integrates metric data collected on biological, physical, and chemical components in upper Wabash River tributaries.

Funding Source: Purdue University Department of Forestry and Natural Resources

Personnel: Emmanuel Frimpong (completed doctoral degree in August 2005) and Peter Hrodey (completed master’s degree in December 2005)

Publications:

· Frimpong, E. A., T. M. Sutton, and T. P. Simon. In review. Ecological health and integrity: integrating concepts with a model for aquatic ecosystem management. Environmental Management.

· Frimpong, E. F., J. G. Lee, and T. M. Sutton. 2006. Cost effectiveness of vegetative filter strips and instream half-logs for ecological restoration. Journal of American Water Resources Association (in press).

· Frimpong, E. A., T. M. Sutton, B. A. Engel, and T. P. Simon. In revision. Physical habitat evaluation, spatial scale effects, and prediction of biotic integrity in agricultural watersheds. Environmental Management 36:899-917.

· Frimpong, E. A., T. M. Sutton, K. J. Lim, P. J. Hrodey, B. Engel, T. P. Simon, J. G. Lee, and D. C. Le Master. 2005. Determination of optimal riparian forest buffer dimensions for stream biota landscape association models using multimetric and multivariate response. Canadian Journal of Fisheries and Aquatic Sciences 62:1-6.

Collaborators: Bernie Engel, John Lee, and Thomas Simon

Half-Log Introductions into Agriculture-Dominated Streams

One of the greatest factors limiting fish productivity in stable, low-gradient, headwater streams is the amount of in-stream cover provided by course woody debris. In order to compensate for this lack of structure, managers often add woody materials into the stream channel to increase cover complexity and overall productivity. In addition to providing valuable habitat features, the placement of woody debris within streams can create pools, increase the retention of sediment and organic materials, stabilize the physical streambed, and create unique channel morphologies. A design typically used by managers in small stream systems is half-log habitat enhancement structures. Half-logs attract juvenile and adult fish by providing overhead cover where it did not previously exist or may have existed but has been since removed. These structures can also provide an additional forage site for fish through the macroinvertebrates and periphyton that colonize them. Half-logs (N = 108) were added to headwater streams (N = 9) of the upper Wabash River basin, Indiana, in July 2003. Each stream contained three paired control and treatment reaches. Treatment sites had added to them four half-logs each, while control sites were spaced a minimum of 100 m upstream and left unaltered. Study sites (25 m in length) were sampled once monthly through October 2003 and April through September 2004 using backpack electrofishing employing a three-pass depletion method. After manipulation, fish abundance was higher at treatment than control sites (mean = 652 and 493 fish, respectively). Similarly, both catch-per-unit-effort (fish/hr) and biomass (g/m²) were higher at treatment sites (mean = 194.65 and 177.96; 4.25 and 2.85, respectively). Species richness and the rela