Bodega Marine Laboratory/Reserve
March 2-4, 2012 |
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Participant Abstracts
Constraints on biological nitrogen fixation across geological time
Joy Cookingham
Graduate Group in Ecology, Land, Air and Water Resources
University of California, Davis
Biological nitrogen (N) fixation—the conversion of atmospheric di-nitrogen (N2) into bio-available ammonium—is a process of significant ecological importance. N limits plant productivity and carbon exchange at the global scale, yet our understanding of the rates and controls of this process are limited, especially for aymbiotic N fixation during litter decomposition. In ecosystems lacking large numbers of symbiotic N2-fixing plants, asymbiotic N fixation has the potential to represent a substantial N input. My study takes advantage of a natural ecological staircase located in Mendocino County, California, composed of five wave-cut terraces each 100,000 years older than the one below. The sequence represents an extreme gradient in nutrient availability, with a nutrient poor pygmy forest at the oldest site and a relatively nutrient rich bishop pine forest at the youngest site. Using the Ecological Staircase as a natural experiment in nutrient limitation, I will examine the response of asymbiotic N fixation during litter decomposition at each terrace. In order to address possible mechanisms responsible for observed patterns, I will conduct two field experiments. First, I will examine the response of N-fixation across terraces in response to fertilization by elements potentially limiting the activity of this process. Second, I will conduct a decomposition experiment with reciprocal transplant of litter from each terrace. This experiment will examine the relative importance of litter quality (i.e. concentration of polyphenols) versus site conditions (i.e. nutrient availability) on N fixation during litter decomposition. This study will provide estimates of N fixation rates with variations in nutrient availability and address possible mechanisms responsible for observed patterns.
H. Eve Robinson
Department of Integrative Biology
University of California, Berkeley
Benthic suspension feeders play a key role in transporting material from planktonic to bottom-dwelling communities by preying upon particles and small organisms suspended in the water column. Variations in the flow environment affect food availability and prey capture by sessile suspension feeders. Turbulence and waves impact zooplankton by increasing encounter rates with predators and limiting swimming behavior or escape responses. Turbulence can also affect the predator by impacting their ability to successfully retain and ingest prey. To address how the fluid environment affects predator-prey interactions in suspension feeding, I characterized the flow environment above a bed of aggregating sea anemones, Anthopleura elegantissima, at two rocky intertidal sites on Bodega Head (Sonoma Coast, California), and measured plankton availability. One site was directly exposed to waves; the other site was located in a harbor, relatively sheltered from incoming swell. The localized flow measurements were also compared to offshore buoy observations and nearshore instruments that measured waves to look for energetic linkages between large-scale and small-scale flow variations. These data will be used to re-create in a laboratory flume the range of flow velocities, turbulence, and waves observed over sea anemones to study small-scale predator-prey interactions between zooplankton prey and benthic suspension feeders.
Michelle E. Afkhami
Department of Evolution and Ecology
University of California, Davis
Niche theory has led to important advancements in the understanding of species coexistence, community assembly, and speciation. Researchers have focused on niche reduction caused by negative species interactions, but the effects of positive interactions (e.g. mutualism and facilitation) have been virtually ignored. Unlike competition/predation, positive interactions can expand the realized niche of a species, even beyond the fundamental niche, by conferring benefits that ameliorate (a)biotic stresses. Partner-generated niche shifts could also cause intra-specific niche differentiation, if individuals that associate with partners have different niches from those that do not. I examined how a fungal endophyte (Neotyphodium sp.) affects the niche of its native grass host, Bromus laevipes, via modeling and experimental approaches. Ecological niche models using survey and climate data indicate that endophyte expands the host niche across its entire range and that differentiation associated with the endophyte is comparable to that observed among species. Five common gardens were also set up at UC Natural Reserves throughout northern/central California to test for niche effects and whether the interaction can be mutualistic. I manipulated endophyte levels in plants from 11 populations prior to planting. Over the last three years, I have found that across all five gardens, plants with high levels of endophyte experienced higher fitness than plants with low levels or no endophyte. The fitness increase was large: ~40% more stems and leaves, ~80% more flowering, and 25% lower mortality for plants with endophyte. Plants with high endophyte levels also receive less natural enemy damage, suggesting an underlying mechanism of endophyte-conferred natural enemy deterrence.
Emily C. Wilson
Department of Biology, University of California, Riverside
School of Natural Sciences
University of California, Merced
With increasing population growth and the predicted consequences of global climate change, renewable approaches to agriculture and forestry are important areas of research. To understand factors that contribute to successful and productive plants we need a better understanding of symbionts such as endophytes—bacteria and fungi inside healthy plant tissue—which can play a role in plant stress protection and growth promotion. Application of these bacteria could drive future efforts in sustainable crops and forestry, however much remains to be studied concerning plant-endophyte relationships and the complex communities of endophytes. Studies of single-endophyte isolates from agricultural plants have demonstrated that bacterial endophytes have beneficial effects on their plant host but little is known about the role of bacterial endophytes in natural ecosystems. Further study is needed concerning the mode of endophyte transmission, the specificity of plant-endophyte relationships, and variability of bacterial endophyte communities throughout host tissues, species, and geographic locations over time. The central hypothesis directing the course of this project is that plants form specific symbioses with host-adapted bacterial endophytes. This hypothesis will be tested in a seasonal study of conifer endophytes isolated from Pinus contorta growing in Tuolumne Meadows, California.
Taraneh Emam
Department of Biology, University of California, Riverside
University of California, Davis
Mine sites can be particularly challenging to restore, as topsoil is often lost, severely disturbed, or contaminated. I applied two treatments used in mine restoration, topsoil addition and soil inoculation, to a waste disposal site at the former Knoxville mercury mine on McLaughlin Natural Reserve. Depths of stockpiled topsoil from 2 — 50 cm were placed atop mine tailings to simulate possible reclamation practices and to vary the levels of stress experienced by plants. Subplots containing the topsoil depth gradient were then inoculated with either arbuscular mycorrhizal (AM) inoculum from a commercial source, rhizosphere soil from nearby native grassland, or were left uninoculated as a control. Plots were seeded with a mixture of native grasses and non-native species recruited from adjacent areas. Contrary to my hypotheses, non-native grass biomass was more responsive to inoculation than native grass biomass. In control plots, biomass of non-native and native grass was similar. In rhizosphere soil treated plots, biomass of non-native grasses was approximately 2.5 times higher in than in controls, while native grass was unaffected. Commercial AM inoculum had no significant effect on either native or non-native grass biomass. Deeper topsoil resulted in higher native grass biomass, and AM colonization of the native grass selected for analysis (Vulpia microstachys) was highest in both shallow and deep extremes of topsoil depth, but there was no interaction between depth and inoculation treatment. These results indicate that while soil inoculation may increase plant biomass in mined areas, it could disproportionately increase growth of less desirable species; thus caution should be used when implementing an inoculation treatment.
Sarah Gravem
Graduate Group in Ecology, Environmental Science and Policy
University of California, Davis
The presence of predators in communities can have cascading effects on lower trophic levels, and recent evidence suggests cascades are often caused by changes in prey behavior rather than actual consumption of prey (non-consumptive indirect effects, NCIE). However, natural field-based studies showing this are rare. Using natural densities and allowing free movement of predators and prey in the field, I demonstrated an NCIE where the predatory seastar Leptasterias hexactis indirectly positively affect microalgae in tidepools by altering the behavior of the herbivorous snail Chlorostoma (Tegula) funebralis. Laboratory and field experiments also show that individual snail states, including increased size, increased hunger level, and high densities of conspecifics, mitigate the fear response of the snail, and may weaken the strength of this NCIE. This result, where phenotypic plasticity alters the strength of an NCIE, has not been demonstrated in other studies. Further, I plan to study how these snail states alter NCIE in the natural tidepool system, and how Leptasterias may exert "remote contro" over algae in Chlorostoma's refuge habitat.
Lindsey K. Albertson
Department of Ecology, Evolution, and Marine Biology
University of California, Santa Barbara
An increasing number of studies have shown that organisms modify physical processes by constructing biological structures (e.g. plant roots, biofilms). However, most of these studies have investigated a single, dominant organism and have rarely investigated the impacts of biological structures from multiple, coexisting species. Here, I ask whether we must account for variation among species that, because of niche differences, each exert a unique influence on physical processes. I use a model system to test how the diversity of benthic, net-spinning caddisflies (Trichoptera) impacts sediment transport in streams. I extend the results of previous studies showing that silk nets of a single species of caddisfly can reduce sediment mobility by asking whether two species have a greater impact than one. In studies conducted in laboratory flumes and experimental stream channels at the Sierra Nevada Aquatic Research Laboratory, I found that the critical shear stress required to initiate sediment movement was significantly higher in streams containing two caddisfly species. The increase in stability appeared to result from spatial partitioning of larvae among pore spaces, with a larger species (Arctopsyche californica) that produces relatively stronger silk building nets at the benthic surface and a smaller species (Ceratopsyche oslari) that produces relatively weaker silk building nets in the subsurface. These results suggest that a quantitative merger of biology and geomorphology may require that we specifically account for variation among species.
Regina J. Dingler
Veterinary Medicine and Epidemiology
University of California, Davis
Lyme borreliosis (LB), caused by Borrelia burgdorferi, and human granulocytic anaplasmosis (HGA), caused by Anaplasma phagocytophilum, are the most common tick-borne diseases in the United States. In California, the bacterial pathogens may be transmitted to humans and/or domesticated animals by Ixodes pacificus, the western black-legged tick. Avian mist nets were opened for 80 hours over a period of 19 weeks at two sites in central California: Quail Ridge Reserve (Napa, California) and Cache Creek Canyon Regional Park (Yolo, California). 143 birds, representing 28 species, were captured. Ticks were removed from 48 birds, yielding 240 larval and 53 nymphal ticks. Quail Ridge was more diverse in terms of avian richness and abundance. Additionally, more ticks, both larval and nymphal, were collected at Quail Ridge (n=272) compared with Cache Creek (n=21). Ectoparasites and avian blood samples were analyzed for B. burgdorferi and A. phagocytophilum infection and previous exposure. This study demonstrates that although these pathogens are likely maintained by rodent reservoirs, birds serve as hosts for subadult I. pacificus. For instance, a juvenile wild turkey captured at Quail Ridge Reserve was heavily infested with nymphal ticks, and supports the hypothesis that ground foraging birds may be important hosts for maintaining tick populations. Further, since nymphal ticks may acquire infections as larvae, birds at these two sites are potentially carrying and/or dispersing infected ticks. Therefore, understanding the seasonality of tick life stages in relation to bird foraging behavior and migratory patterns may help clarify the disease ecology of these two pathogens.
Andrea Grunst
Department of Evolution, Ecology, and Organismal Biology
University of California, Riverside
Tradeoffs between self-maintenance and reproduction are theorized to constrain alternative life histories and reproductive strategies, and may also constrain expression of expensive sexual ornaments. However, researchers have only recently begun to study sexual ornaments as life history investments. There is a trade-off between the development of these ornaments and other allocation alternatives. In yellow warblers (Setophaga petechia), I am investigating the hypothesis that males with high levels of sexual pigmentation invest in pigmentation and mating effort at the expense of oxidative status and paternal care. Development of pigment ornaments and intense male-male mating competition may generate oxidative costs by expending molecules with antioxidant potential and increasing metabolic rate and production of pro-oxidants. Increased time devoted to mating effort and declines in body condition and oxidative status may in turn reduce paternal performance. On the other hand, I am also exploring the possibility that highly pigmented males invest in mating over paternal care only in certain environments or stages of the breeding cycle, such as when territory disputes are intense. To address my hypotheses, I capture warblers early in the season and measure pigmentation using digital photographs and reflectance spectra obtained from feathers. I also obtain blood samples to measure oxidative status. Throughout the season, I video-record nests to determine song and paternal provisioning rates. Further, I present a model territorial intruder near nestling-stage nests to assess territoriality and whether territorial challenge differentially affects paternal effort in males differing in pigmentation. Results provide support for hypotheses, but additional work including a pigment manipulation will solidify interpretation.
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