Your search keyword '"Robert E. Espinoza"' showing total 3 results

1. Teaching Biology in the Field: Importance, Challenges, and Solutions

Author

Robert E. Espinoza, Harry W. Greene, Robin Wall Kimmerer, Thomas L. Fleischner, David W. Winkler, Steven Pace, Eileen A. Lacey, Stephen C. Trombulak, Hilary M. Swain, Lisa Zander, Gretchen A. Gerrish, Saul Weisberg, and Julia K. Parrish

Subjects

0106 biological sciences, Field (physics), 05 social sciences, 050301 education, Engineering ethics, Biology, General Agricultural and Biological Sciences, 010603 evolutionary biology, 0503 education, 01 natural sciences

Published

2017

2. The importance of physiological ecology in conservation biology

Author

K. T. Castle, K. Dean-Bradley, Kenneth E. Nussear, Linda C. Zimmerman, Todd C. Esque, Christopher R. Tracy, L.A. DeFalco, C. Richard Tracy, Robert E. Espinoza, and A. M. Barber

Subjects

education.field_of_study, Herbivore, Tortoise, Ecology, Population, Endangered species, Plant Science, Biology, Optimal foraging theory, Population cycle, Seasonal breeder, Animal Science and Zoology, Conservation biology, education

Abstract

Many of the threats to the persistence of populations of sensitive species have physiological or pathological mechanisms, and those mechanisms are best understood through the inherently integrative discipline of physiological ecology. The desert tortoise was listed under the Endangered Species Act largely due to a newly recognized upper respiratory disease thought to cause mortality in individuals and severe declines in populations. Numerous hypotheses about the threats to the persistence of desert tortoise populations involve acquisition of nutrients, and its connection to stress and disease. The nutritional wisdom hypothesis posits that animals should forage not for particular food items, but instead, for particular nutrients such as calcium and phosphorus used in building bones. The optimal foraging hypothesis suggests that, in circumstances of resource abundance, tortoises should forage as dietary specialists as a means of maximizing intake of resources. The optimal digestion hypothesis suggests that tortoises should process ingesta in ways that regulate assimilation rate. Finally, the cost-of-switching hypothesis suggests that herbivores, like the desert tortoise, should avoid switching food types to avoid negatively affecting the microbe community responsible for fermenting plants into energy and nutrients. Combining hypotheses into a resource acquisition theory leads to novel predictions that are generally supported by data presented here. Testing hypotheses, and synthesizing test results into a theory, provides a robust scientific alternative to the popular use of untested hypotheses and unanalyzed data to assert the needs of species. The scientific approach should focus on hypotheses concerning anthropogenic modifications of the environment that impact physiological processes ultimately important to population phenomena. We show how measurements of such impacts as nutrient starvation, can cause physiological stress, and that the endocrine mechanisms involved with stress can result in disease. Finally, our new syntheses evince a new hypothesis. Free molecules of the stress hormone corticosterone can inhibit immunity, and the abundance of "free corticosterone" in the blood (thought to be the active form of the hormone) is regulated when the corticosterone molecules combine with binding globulins. The sex hormone, testosterone, combines with the same binding globulin. High levels of testosterone, naturally occurring in the breeding season, may be further enhanced in populations at high densities, and the resulting excess testosterone may compete with binding globulins, thereby releasing corticosterone and reducing immunity to disease. This sequence could result in physiological and pathological phenomena leading to population cycles with a period that would be essentially impossible to observe in desert tortoise. Such cycles could obscure population fluctuations of anthropogenic origin.

Published

2006

3. Phylogenetic relationships in the iguanid lizard genus Liolaemus: multiple origins of viviparous reproduction and evidence for recurring Andean vicariance and dispersal

Author

Robert E. Espinoza, Allan Larson, J. Robert Macey, and James A. Schulte

Subjects

Monophyly, Squamata, biology, Ecology, Phylogenetics, Evolutionary biology, Vicariance, Biological dispersal, Phymaturus, Liolaemus, Iguania, biology.organism_classification, Ecology, Evolution, Behavior and Systematics

Abstract

Phylogenetic relationships within the iguanid lizard genus Liolaemus are investigated using 1710 aligned base positions (785 phylogenetically informative) of mitochondrial DNA sequences, representing coding regions for eight tRNAs, ND2, and portions of ND1 and COL Sixty new sequences ranging in length from 1736 to 1754 bases are compared with four previously reported sequences. Liolaemus species form two well-supported monophyletic groups of subgeneric status, Liolaemus and Eulaemus. These subgenera appear to have separated at least 12.6 million years ago based on the amount of molecular evolutionary divergence between them. Hypotheses that species occurring in the Andes, west of the Andes, and east of the Andes, each comprise distinct monophyletic groups are independently rejected statistically. The shortest estimate of phylogeny suggests mat Liolaemus originated either in the Andes or the eastern lowlands. Numerous evolutionary shifts have occurred between the Andes, and the eastern and western lowlands, suggesting recurring vicariance and dispersal. Species occurring at high elevations or high latitudes usually have viviparous reproduction. Depending on whether parity mode is considered reversible in Liolaemus, the most parsimonious reconstruction supports at least six independent origins of viviparity or at least three gains followed by three losses of viviparity among die 60 Liolaemus lineages examined.

Published

2000