Your search keyword '"Gorman, Owen T."' showing total 4 results

1. Effect of light intensity and substrate type on siscowet lake trout (Salvelinus namaycush siscowet) predation on deepwater sculpin (Myoxocephalus thompsonii).

Author

Keyler, Trevor D., Hrabik, Thomas R., Mensinger, Allen F., Rogers, Loranzie S., and Gorman, Owen T.

Subjects

LAKE trout, LIGHT intensity, PREDATION, MOLECULAR spectra, PREDATORY animals, PHOTONS

Abstract

Foraging characteristics of siscowet lake trout (Salvelinus namaycush siscowet) on deepwater sculpin (Myoxocephalus thompsonii) were studied under ecologically relevant downwelling light intensities (9.0 × 108 to 1.62 × 1011 photons m−2 s−1) and emission spectrum (500–510 nm) on varying substrates (gravel, sand, and black fabric). Siscowet reaction distance within our trials increased with light intensity up to 6.0 × 109 photons m−2 s−1, after which reaction distance remained constant with additional increases in light intensity following the Michaelis–Menten saturation function. Reaction distances were not affected by substrate type under any light intensity. The number of prey captures also increased with increasing light intensity, with most orientations toward prey occurring within the siscowet's forward sector (± 0°–60°, where 0° represents the tip of the siscowet rostrum). Finally, the overall probability of prey capture was positively related to reaction distance at each light intensity. Results suggest that siscowet can visually forage on benthic prey at great depth in Lake Superior, and reaction distance (≤ 27 cm) to sculpin may not diminish until depths exceed 200 m (6.00 × 109 photons m−2 s−1). [ABSTRACT FROM AUTHOR]

Published

2019

2. Ups and Downs of Burbot and Their Predator Lake Trout in Lake Superior, 1953–2011.

Author

Gorman, Owen T. and Sitar, Shawn P.

Subjects

BURBOT, FISH communities, PREDATORY animals, SEA lamprey, FISH populations, SALMONIDAE

Abstract

The fish community of Lake Superior has undergone a spectacular cycle of decline and recovery over the past 60 years. A combination of Sea LampreyPetromyzon marinusdepredation and commercial overfishing resulted in severe declines in Lake TroutSalvelinus namaycush, which served as the primary top predator of the community. BurbotLota lotapopulations also declined as a result of Sea Lamprey depredation, largely owing to the loss of adult fish. After Sea Lamprey control measures were instituted in the early 1960s, Burbot populations rebounded rapidly but Lake Trout populations recovered more slowly and recovery was not fully evident until the mid-1980s. As Lake Trout populations recovered, Burbot populations began to decline, and predation on small Burbot was identified as the most likely cause. By 2000, Burbot densities had dropped below their nadir in the early 1960s and have continued to decline, with the densities of juveniles and small adults falling below that of large adults. Although Burbot populations are at record lows in Lake Superior, the density of large reproductive adults remains stable and a large reserve of adult Burbot is present in deep offshore waters. The combination of the Burbot's early maturation, long life span, and high fecundity provides the species with the resiliency to remain a viable member of the Lake Superior fish community into the foreseeable future. Received October 1, 2012; accepted July 9, 2013 [ABSTRACT FROM AUTHOR]

Published

2013

3. RESTORING PISCIVOROUS FISH POPULATIONS IN THE LAURENTIAN GREAT LAKES CAUSES SEABIRD DIETARY CHANGE.

Author

Hebert, Craig E., Chip Weseloh, D. V., Idrissi, Abde, Arts, Michael T., O'Gorman, Robert, Gorman, Owen T., Locke, Brian, Madenjian, Charles P., and Roseman, Edward F.

Subjects

BIOTIC communities, FATTY acids, LARUS argentatus, LARUS, SEA birds, FOOD chains, PREDATORY animals, BIRDS of prey, STABLE isotopes

Abstract

Ecosystem change often affects the structure of aquatic communities thereby regulating how much and by what pathways energy and critical nutrients flow through food webs. The availability of energy and essential nutrients to top predators such as seabirds that rely on resources near the water's surface will be affected by changes in pelagic prey abundance. Here, we present results from analysis of a 25-year data set documenting dietary change in a predatory seabird from the Laurentian Great Lakes. We reveal significant declines in trophic position and alterations in energy and nutrient flow over time. Temporal changes in seabird diet tracked decreases in pelagic prey fish abundance. As pelagic prey abundance declined, birds consumed less aquatic prey and more terrestrial food. This pattern was consistent across all five large lake ecosystems. Declines in prey fish abundance may have primarily been the result of predation by stocked piscivorous fishes, but other lake-specific factors were likely also important. Natural resource management activities can have unintended consequences for nontarget ecosystem components. Reductions in pelagic prey abundance have reduced the capacity of the Great Lakes to support the energetic requirements of surface-feeding seabirds. In an environment characterized by increasingly limited pelagic fish resources, they are being offered a Hobsonian choice: switch to less nutritious terrestrial prey or go hungry. [ABSTRACT FROM AUTHOR]

Published

2008

4. Publisher Correction to: Effect of light intensity and substrate type on siscowet lake trout (Salvelinus namaycush siscowet) predation on deepwater sculpin (Myoxocephalus thompsonii).

Author

Keyl, Trevor D., Hrabik, Thomas R., Mensinger, Allen F., Rogers, Loranzie S., and Gorman, Owen T.

Subjects

LAKE trout, LIGHT intensity, PREDATION, MANUFACTURING processes, PREDATORY animals

Abstract

Due to a mistake during the production process, the online/HTML version of the original article was published under the terms of the Creative Commons Attribution 4.0 International License. The article is not open access and no special license applies. The original article has been corrected. [ABSTRACT FROM AUTHOR]

Published

2020