The Importance of the mid-trophic layers in ecosystem structure, process and function: the relationship between the Eastern Pacific Gray Whale (Eschrichtius robustus) and mysids (order Mysidacea) in Clayoquot Sound.

Burnham, Rianna Elizabeth

31 July 2012

While the impact of top-down and bottom-up drivers of ecosystem functions has been given considerable argument, here the mid-trophic level is given focus. In marine systems the influence of mid-trophic level species operates in a ‘wasp-waisted’ structure, where they exert regulatory control by acting as a valve to energy flow between large seasonal pulses of primary production and upper level species. In this study I examine the impact of foraging eastern Pacific gray whales (Eschrichtius robustus) on mysid species at the ‘wasp-waist’ (Order Mysidacea), and vice versa, at feeding sites in Clayoquot Sound off the west coast of Vancouver Island. I appraise previously unknown aspects of the ‘prey-scape’, and further explore life-history traits that allow prey populations to persist in a given species array. The set of problems that I examine are all based on the whales’ top-down forcing in a localized area, and the prey response. I use several scales of observation as dictated by the nature of each question. I examine top down forcing and subsequent prey switching over a 25-year period, the variation in foraging intensity over a 15 year period, the differential prey species’ response to persistent predatory pulses that creates dominance and diversity among the mysid species flock, and whales’ within-season response to possible satiation. Each of these studies is linked by the common goal of illuminating the intimate relationship between predator and prey. Gray whale foraging has decimated amphipod prey resources in the study area past the point of recovery over the last 25 years, and the prey resource is no longer a viable energy source. This has led to the abandonment of benthic-feeding by gray whales in the area, and a switch to mysids as a primary prey source. It is in investigating these mysid species’ ability to rebound following severe foraging pressure that I uncovered two principal life history strategies, one held by the single dominant mysid species, and another used by 9 or 10 others consistently sampled. The capacity for renewal of mysid swarms is imperative if Clayoquot Sound is to persist as a productive foraging area for gray whales. The pattern of this relationship that I present, based on a 15 year span, was previously unknown. Intense foraging of mysids by gray whales during a summer affects the reserves for the following season, leading to a biennial fluctuation in the number of whales the area can sustain, although some of the heaviest foraging seasons require several years to show mysid recovery. I state 9 or 10 other species, as through the intense examination of mysids here, there may be a new species designated. The data gathered by myself and colleagues over the past 25 years that whales have been studied in Clayoquot Sound, clearly shows that predation by baleen whales can affect the future quality of their foraging areas, as well as influencing the population, life-stage and diversity of prey species. My work furthers knowledge in life history characteristics of the mysid species present in the study area, particularly growth and reproduction, and ability to capitalize on a release of predation pressure over winter to recover. That, in turn creates a series of following questions about how different life history strategies make use of a variety of possible energy pathways to stabilize ecosystems at least at discrete spatial scales. / Graduate

marine ecology

gray whales

mysids

trophic dynamics

Allelopathy in the Non-Native Macrophyte, Myriophyllum Spicatum and its Influence on Trophic Dynamics in Aquatic Systems

Sullivan, Daniel J

14 August 2015

Non-native macrophytes structurally impact aquatic assemblages, yet little is known regarding how they influence energy pathways in freshwater ecosystems. Allelopathy in Eurasian watermilfoil- Myriophyllum spicatum has been shown to target basal epiphytic organisms resulting in differences in assemblage structure of colonizing epiphyton between M. spicatum and native M. sibiricum. I conducted a growth chamber experiment to investigate the hypothesis that differences in assemblage structure of colonizing epiphyton between these two macrophytes influence trophic dynamics within aquatic systems. My data suggest M. spicatum produces higher concentrations of allelochemicals, resulting in a more diverse epiphytic assemblage compared to M. sibiricum. This could result in potential transformation of trophic dynamics by decoupling carbon as it flows from primary producer to primary consumer. This work identifies a contributing mechanism responsible for M. spicatum invasiveness and provides new insight in its ecology and management of this non-native macrophyte.

aquatic plants

myriophyllum

epiphyton

invasive species

trophic dynamics

aquatic ecology

Examination of Trophic Dynamics of the Mangrove Ecosystem in Port Everglades, Florida, USA, Using Stable Isotope Ratios

Parks, Kelly

01 April 2013

Mangrove communities are unique environments that line coastlines in tropical and subtropical latitudes. In Florida, four mangrove tree species dominate these communities and are accompanied by other primary producers, infaunal, epifaunal, and juvenile faunal species that together form the base of a complex, chiefly detritus-based food web. In an effort to evaluate mangrove communities in Port Everglades, Florida, tissue samples were taken from a diversity of mangrove- associated producer and consumer species from three mangrove sites. Stable carbon and nitrogen isotope ratios were used to establish patterns of energy flow of mangrove material, examine the influence of detrital material, and identify isotopic differences among mangrove species. R.mangle was the most depleted in δ13C, -34.11 to -26.19‰, while C.erectus was the most enriched, -29.91 to -25.30‰. This pattern mirrors the documented pattern of proximity to the waterline, but this pattern was not the same in δ15N, as C.erectus exhibited the narrowest range of δ15N values, -1.95 to 5.40‰. Significant differences were found in δ15N and δ13C signatures of the mangrove species among the tissue types, sampling sites, and trophic linkages among three sample sites, which could indicate differences between natural and anthropogenic influences, such as increased nitrate from a nearby residential area. Specifically, site 1, the only site located directly on the Intracoastal Waterway, differed significantly from sites 2 and 3, both of which were indirectly connected to the waterway. Results also established unique trophic levels, with primary producers at the bottom and carnivorous fish at the top. Slight differences among the trophic dynamics, such as a shift in diet specifically with fish species, among the sites revealed a possible influence of restricted tidal flow from mangrove communities.

Mangroves

stable isotopes

trophic dynamics

Florida

Marine Biology

Fertilization and plant litter effects on the plant and epigeal arthropod communities

Patrick, L Brian

30 November 2009

No description available.

Biology

Ecology

biodiversity

nitrogen

fertilization

plant litter

trophic dynamics

epigeal community

Uptake of Mercury and Relationship to Food Habits of Selected Fish Species in the Shenandoah River Basin, Virginia

Murphy, Gregory W.

17 August 2004

Mercury poses significant challenges to human health and fisheries management. Historical industrial practices in Waynesboro, Virginia left portions of the Shenandoah River basin contaminated with mercury and stringent health advisories for fish consumption. I investigated processes affecting the bioaccumulation of mercury in Catostomus commersoni, Ictalurus punctatus, Lepomis auritus, and Micropterus dolomieu by studying food habits, total mercury and methylmercury in common prey items, and bioaccumulation dynamics of methylmercury in the mercury contaminated South River and South Fork of the Shenandoah River and uncontaminated North River. Additionally, I evaluated sexual and seasonal variations of total mercury in M. dolomieu in the South Fork of the Shenandoah River. Algae, aquatic insects, crayfish, detritus, and fish accounted for 75-97% of the diet. Total mercury in aquatic invertebrates and forage fish in contaminated rivers ranged from 66.7-398.3 and 198.0-594.9 ng/g wet weight, while total mercury in aquatic invertebrates and forage fish in the reference river were 4.4 and 29.3 ng/g. Model simulations indicated that dietary pathways accounted for 87% of methylmercury uptake by fish in contaminated rivers, but only 57% in the reference river. Total mercury in M. dolomieu was 19-20% higher in females than males and 14-21% higher during spring than summer and fall. Results of this study indicate that bioenergetics-based bioaccumulation models are valuable tools for evaluating field data, identifying processes critical to contaminant accumulation, and comparing outcomes of alternative management options associated with pollution control, ecosystem management, and/or restoration activities for management guidance prior to costly expenditures. / Master of Science

aquatic invertebrates

bioaccumulation model

fish communities

bioenergetics

methylmercury

mercury

trophic dynamics

Trophic Dynamics and Feeding Ecology of the Southeast Florida Coastal Pelagic Fish Community

Moore, Travis Allan

01 March 2014

The combined methods of stomach content analysis and stable 15N and 13C isotope biochemistry analysis were used to investigate the trophic dynamics and feeding ecology of coastal pelagic fishes in the waters off southeastern Florida, USA. The coastal pelagic fish complex includes blackfin tuna Thunnus atlanticus, dolphinfish Coryphaena hippurus, king mackerel Scomberomorus cavalla, little tunny Euthynnus alletteratus, skipjack tuna Katsuwonus pelamis, and wahoo Acanthocybium solandri. These coastal teleosts, particularly the tunas and wahoo, are primarily targeted by recreational anglers. However, there is a shortage of available trophic and diet composition data concerning these fishes of the coastal pelagic ecosystem. Stomach and muscle tissue samples were collected from the species of various lengths over a three-year period from March 2010 and March 2013. Across all six species, teleost fishes dominated the prey with an average 64.5% by occurrence, 63.7% by number, and 89.9% by weight. There were two dominant prey families: Clupeidae and Carangidae. Dolphinfish showed the lowest diet overlap among the six species, due to the highly diverse diet. The highest diet overlap occurred between king mackerel and little tunny. The mean δ15N ranged from 8.21 ‰ (wahoo) to 13.18 ‰ (king mackerel), and the mean δ13C ranged from -18.41 ‰ (king mackerel) to -16.70 ‰ (dolphinfish). Blackfin tuna exhibited the largest δ15N range (7.22 to 13.21 ‰), as well as the largest δ13C range (-19.13 to -12.99 ‰). The δ15N and δ13C signatures in the muscle tissue showed evidence of shifts to higher trophic levels with an increase in fish size and the formation of distinct trophic groups among the coastal pelagic predators. The δ13C also suggested an inshore-offshore spatial relationship among the coastal pelagic fish. The trophic dynamics and feeding ecology data generated by this study will provide valuable baseline data for the coastal pelagic complex and future ecosystem studies.

Coastal Pelagic

Stomach Content Analysis

Stable Isotopes

δ15N

δ13C

Ecosystem

Trophic Dynamics

Food Web

Feeding Ecology

Marine Biology

Impacts of artificial light at night on space use and trophic dynamics of urban riparian mammals in Columbus, Ohio

Gilboy, Michael Joseph

January 2022

No description available.

Ecology

Environmental Science

Natural Resource Management

Wildlife Conservation

Wildlife Management

artificial light at night

ALAN

urban mammals

mammal communities

mammal space use

aquatic-riparian linkages

food webs

space use

trophic dynamics

camera traps

live traps