Your search keyword '"Chesson, L"' showing total 5 results

1. Terrestrial birds in coastal environments: metabolic rate and oxidative status varies with the use of marine resources.

Author

Tapia-Monsalve, Romina, Newsome, Seth D., Sanchez-Hernandez, Juan C., Bozinovic, Francisco, Nespolo, Roberto, and Sabat, Pablo

Subjects

COASTAL ecosystem health, PASSERIFORMES, BASAL metabolism, OXIDATIVE stress, OSMOREGULATION, STABLE isotopes

Abstract

Life in saline environments represents a major physiological challenge for birds, particularly for passerines that lack nasal salt glands and hence are forced to live in environments that do not contain salty resources. Increased energy costs associated with increased salt intake, which in turn increases the production of reactive oxygen species, is likely a major selection pressure for why passerines are largely absent from brackish and marine environments. Here we measured basal metabolic rates (BMR) and oxidative status of free-ranging individuals of three species of Cinclodes, a group of passerine birds that inhabit marine and freshwater habitats in Chile. We used a combination of carbon, nitrogen, and hydrogen isotope data from metabolically active (blood) and inert (feathers) tissues to estimate seasonal changes in marine resource use and infer altitudinal migration. Contrary to our expectations, the consumption of marine resources did not result in higher BMR values and higher oxidative stress. Specifically, the marine specialist C. nigrofumosus had lower BMR than the other two species (C. fuscus and C. oustaleti), which seasonally switch between terrestrial and marine resources. C. fuscus had significantly higher total antioxidant capacity than the other two species (C. nigrofumosus and C. oustaleti) that consumed a relatively high proportion of marine resources. Nearly all studies examining the effects of salt consumption have focused on intraspecific acclimation via controlled experiments in the laboratory. The mixed results obtained from field- and lab-based studies reflect our poor understanding of the mechanistic link among hydric-salt balance, BMR, and oxidative stress in birds. [ABSTRACT FROM AUTHOR]

Published

2018

2. Applying the principles of isotope analysis in plant and animal ecology to forensic science in the Americas.

Author

Chesson, Lesley A., Barnette, Janet E., Bowen, Gabriel J., Brooks, J. Renée, Casale, John F., Cerling, Thure E., Cook, Craig S., Douthitt, Charles B., Howa, John D., Hurley, Janet M., Kreuzer, Helen W., Lott, Michael J., Martinelli, Luiz A., O’Grady, Shannon P., Podlesak, David W., Tipple, Brett J., Valenzuela, Luciano O., and West, Jason B.

Subjects

PLANT ecology, ANIMAL ecology, FORENSIC sciences, STABLE isotopes, RADIOISOTOPES

Abstract

The heart of forensic science is application of the scientific method and analytical approaches to answer questions central to solving a crime: Who, What, When, Where, and How. Forensic practitioners use fundamentals of chemistry and physics to examine evidence and infer its origin. In this regard, ecological researchers have had a significant impact on forensic science through the development and application of a specialized measurement technique—isotope analysis—for examining evidence. Here, we review the utility of isotope analysis in forensic settings from an ecological perspective, concentrating on work from the Americas completed within the last three decades. Our primary focus is on combining plant and animal physiological models with isotope analyses for source inference. Examples of the forensic application of isotopes—including stable isotopes, radiogenic isotopes, and radioisotopes—span from cotton used in counterfeit bills to anthrax shipped through the U.S. Postal Service and from beer adulterated with cheap adjuncts to human remains discovered in shallow graves. Recent methodological developments and the generation of isotope landscapes, or isoscapes, for data interpretation promise that isotope analysis will be a useful tool in ecological and forensic studies for decades to come. [ABSTRACT FROM AUTHOR]

Published

2018

3. Unexpected hydrogen isotope variation in oceanic pelagic seabirds.

Author

Ostrom, Peggy, Wiley, Anne, Rossman, Sam, Stricker, Craig, and James, Helen

Subjects

HYDROGEN isotopes, SEA birds, BIOGEOGRAPHY, MIGRATORY animals, METEOROLOGICAL precipitation

Abstract

Hydrogen isotopes have significantly enhanced our understanding of the biogeography of migratory animals. The basis for this methodology lies in predictable, continental patterns of precipitation δD values that are often reflected in an organism's tissues. δD variation is not expected for oceanic pelagic organisms whose dietary hydrogen (water and organic hydrogen in prey) is transferred up the food web from an isotopically homogeneous water source. We report a 142 ‰ range in the δD values of flight feathers from the Hawaiian petrel ( Pterodroma sandwichensis), an oceanic pelagic North Pacific species, and inquire about the source of that variation. We show δD variation between and within four other oceanic pelagic species: Newell's shearwater ( Puffinus auricularis newellii), Black-footed albatross ( Phoebastria nigripes), Laysan albatross ( Phoebastria immutabilis) and Buller's shearwater ( Puffinus bulleri). The similarity between muscle δD values of hatch-year Hawaiian petrels and their prey suggests that trophic fractionation does not influence δD values of muscle. We hypothesize that isotopic discrimination is associated with water loss during salt excretion through salt glands. Salt load differs between seabirds that consume isosmotic squid and crustaceans and those that feed on hyposmotic teleost fish. In support of the salt gland hypothesis, we show an inverse relationship between δD and percent teleost fish in diet for three seabird species. Our results demonstrate the utility of δD in the study of oceanic consumers, while also contributing to a better understanding of δD systematics, the basis for one of the most commonly utilized isotope tools in avian ecology. [ABSTRACT FROM AUTHOR]

Published

2014

4. Deconvolution of isotope signals from bundles of multiple hairs.

Author

Remien, Christopher, Adler, Frederick, Chesson, Lesley, Valenzuela, Luciano, Ehleringer, James, and Cerling, Thure

Subjects

HAIR physiology, SEGMENTAL analysis technique (Biomechanics), OXYGEN isotopes, FORENSIC sciences, MATHEMATICAL models

Abstract

Segmental analysis of hair has been used in diverse fields ranging from forensics to ecology to measure the concentration of substances such as drugs and isotopes. Multiple hairs are typically combined into a bundle for segmental analysis to obtain a high-resolution series of measurements. Individual hair strands cycle through multiple phases of growth and grow at different rates when in the growth phase. Variation in growth of hair strands in a bundle can cause misalignment of substance concentration between hairs, attenuating the primary body signal. We developed a mathematical model based on the known physiology of hair growth to describe the signal averaging caused by bundling multiple hairs for segmental analysis. The model was used to form an inverse method to estimate the primary body signal from measurements of a hair bundle. The inverse method was applied to a previously described stable oxygen isotope chronology from the hair of a murder victim and provides a refined interpretation of the data. Aspects of the reconstruction were confirmed when the victim was later identified. [ABSTRACT FROM AUTHOR]

Published

2014

5. The influence of diet and water on the stable oxygen and hydrogen isotope composition of Chironomidae (Diptera) with paleoecological implications.

Author

Wang, Yiming V., O'Brien, D. M., Jenson, J., Francis, D., and Wooller, M. J.

Subjects

DIET, HEALTH, WATER, OXYGEN, NONMETALS, REFRIGERANTS, CHIRONOMIDAE

Abstract

Stable oxygen and hydrogen isotope analyses of fossil aquatic organisms, such as the chitinous head capsules of chironomid larvae (Chironomidae: Diptera), are promising proxies for inferring paleoecological conditions. In order for analyses of stable oxygen (δ18O) and hydrogen isotope ratios (δ2H) of fossil chironomid head capsules to be used effectively in paleoecological research, it is necessary to understand the factors controlling their stable oxygen and hydrogen composition. We cultured chironomid larvae in two isotopically distinct waters under controlled, replicated laboratory conditions. Chironomid larvae were fed on identical diets, to examine the degree to which water and diet influence the δ18O and δ2H of these organisms. We used a two-end member mixing model to determine the proportional contributions of oxygen and hydrogen from water to the oxygen and hydrogen of chironomid larvae. Our experiment demonstrated that 69.0 ± 0.4% of oxygen and 30.8 ± 2.6% of hydrogen in chironomid larvae are derived from habitat water. Our results show that oxygen isotopes from chironomid remains can better constrain past habitat water isotopic changes compared to hydrogen, due to 69% of the chironomid oxygen being influenced by habitat water. Our data add to a small but growing suite of comparative data on the sources of oxygen and hydrogen in animal tissues, and provide the first such analyses from aquatic insects. [ABSTRACT FROM AUTHOR]

Published

2009