Thermal Ecology of the Western Fence Lizard, Sceloporus Occidentalis PDF Download

Author: Samuel M. McGinnis
Publisher:
ISBN:
Category :
Languages : en
Pages : 162

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Author: Kenneth John Halama
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ISBN:
Category : Lizards
Languages : en
Pages : 438

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Author: Robert P. Pelletier
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Category : Reptiles
Languages : en
Pages : 86

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Western Fence lizards (Sceloporus occidentalis) are a geographically widespread species that would benefit from adapting their microhabitat use and morphology to better suit the local habitat types they inhabit. To test for such differences, I used visual encounter surveys to assess the microhabitat use of the lizards and collected morphological data to evaluate differences between populations in different habitats. I observed the lizards at three sites representing three habitat types, including a suburban road in Turlock, Stanislaus Co., CA; a rocky cliff in Knights Ferry Recreational Area, Stanislaus Co., CA; and a Riparian forest in Caswell Memorial State Park, Ripon, San Joaquin Co., CA. My prediction that suburban road lizards would be generalists was supported; however, while there was evidence for morphological adaptation for reduced climbing ability and small body size, there was not support for improved running speed to facilitate escape to dense vegetated shelters. My prediction that rocky cliff lizards would be rock specialists was supported; the data showed adaptations for improved running, jumping, and climbing abilities on flat rocks along with a compressed body for taking refuge in tight rock crevices. My prediction that riparian forest lizards would specialize in using the tree microhabitat was not supported; as a result, my prediction that their morphology would be adapted for running, jumping, and broad tree climbing was disproven although they did exhibit a robust body. Instead the riparian forest population appeared better adapted for crypsis while making use of leaf litter and twigs on the ground. My results suggest that Western Fence Lizard populations do have shifts in microhabitat use in different habitat types and have means of adjusting their morphology to better suit their environment, be it through local adaptation or phenotypic plasticity.

Author: Matthew S. Covill
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Category : Lizards
Languages : en
Pages : 188

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Author: Par Singhaseni
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Category : Sceloporus occidentalis
Languages : en
Pages : 62

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Author: Paul Backus
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Category : Habitat (Ecology)
Languages : en
Pages : 0

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Comparisons among core and peripheral populations of animals for patterns of habitat use may be an important step in an area of ecological research: the quest to understand the mechanisms underlying species range boundaries. My research on the Western Fence Lizard, Sceloporus occidentalis, at the northwestern edge of the species' geographic range, is intended to lay the groundwork for future analyses of peripheral populations. Sceloporus occidentalis is a propitious species for studying peripheral animal populations because (1) relative to dryland habitats more typical of the species nearer the core of its geographic range, the peripheral population resides in a relatively unique beach-edge maritime habitat, and (2) it is found in high local abundance, is easy to observe and capture, and has low vagility relative to birds and mammals. My research addresses the habitat preferences, dispersal tendencies, and spatial distribution among individuals of S. occidentalis in a population at the species geographic extreme in western Washington. In 2013-2014 I captured, measured, and marked 359 lizards on the central beach in an apparent metapopulation along the Washington coast west of Marysville, WA. I recorded detailed habitat characteristics for every 10-meter stretch of beach using the line-intercept method (transect was set perpendicular to beach edge) and used Multidimensional Scaling analysis to correlate habitat characteristics with lizard sighting locations, thereby determining which sections of coastal beach edge were most heavily used by fence lizards. Similarity Percentage (SIMPER) analysis was used to determine which habitat characteristics were associated with most of the difference between occupied and unoccupied habitat areas. These characteristics and their relative influences on habitat differences were: distance to nearest patch of sun-exposed soil on the slope above the beach (45%), the abundance of nanohabitats (i.e. different substrata or log surfaces) in the log field below the slope (22%), the number of exposed soil patches on the beach slope (16%), the length (between slope base and beach-edge) of the log field on the beach below the slope (10%), and the relative amount of exposed soil in standard plots on the slope above the beach (5%). Chi-square analysis revealed that lizards were more likely to bask on log surfaces than on sand and leaf litter surfaces, perhaps because (1) body temperature can be more finely regulated on logs by adjusting angle of the body towards the sun, and (2) antipredator cover is nearer when on a log. Hatchling lizards were more likely than adults to be found on sand substratum. Based on proportions of age and sex classes that dispersed and the distances moved, I inferred that younger lizards were more likely to disperse longer distances than adults along Spee-Bi-Dah beach. Lizard sighting locations were documented in ArcGIS and the degree of overlap in habitat characteristics with lizard locations determined through Analysis of Similarity, which revealed lizards to be clumped around patches of prime habitat. A reasonable inference is that high population density and intraspecific competition in these habitat patches may be pushing lizards to disperse into suboptimal habitat. However, invasive plant species, particularly Himalayan blackberry, rapidly colonize open soil patches on the beach slope, restricting the lizards' access to habitat necessary for nesting and hibernation, and reducing habitat available for population growth or range expansion. Habitat degradation by invasive species and humans is likely a significant factor in the apparent decline of fence lizard populations along the Washington coast.

Author: Neil Greenberg
Publisher:
ISBN:
Category : Animal behavior
Languages : en
Pages : 368

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Author: U.S. Fish and Wildlife Service
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Category : Animals
Languages : en
Pages : 826

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Author: Bruce Aaron Kingsbury
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Category : Body temperature
Languages : en
Pages : 246

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Author: Nassima Mahdjouba Bouzid
Publisher:
ISBN:
Category :
Languages : en
Pages : 171

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I am fascinated by intraspecific variation-by both its sources and its potential implications for how organisms interact with their environments. The importance of intraspecific variation for predicting species responses to climate change has recently become a research priority. Differences in the sources of intraspecific variation0́3genetic divergence, phenotypic plasticity, and drift0́3can have profoundly different outcomes for species responses. Variation in traits produced by heritable differences in genes will be sensitive to future selection, while variation produced by phenotypic plasticity may be buffered. Time and again, mechanistic studies of species responses have highlighted the importance of considering trait variation to predict idiosyncratic responses, and the sources of trait variation must also be considered. I studied intraspecific variation in Western Fence Lizards (Sceloporus occidentalis) at three spatial scales and three levels of organization. In Chapter 1 I investigated species-wide phylogeographic patterns and demographic scenarios throughout western North America. In Chapter 2 I characterized clinal variation in genotypes and phenotypes and gene flow along an elevation gradient in Yosemite National Park. In Chapter 3 I disentangled the genetic and plastic constituents of divergent phenotypes in a lab rearing experiment. My dissertation research provides an integrative framework for studying local adaptation in a polymorphic and well-established vertebrate system. Chapter 1 is the culmination of over two decades of research on phylogeographic structure within S. occidentalis. We sampled 108 individuals from 83 localities throughout the range in western North America. We used 4,555 SNPs from ddRADseq to characterize population structure and estimate demographic history. We found five genetically distinct populations including: one in the southwest, south of the Transverse Ranges; two west of the Sierra Nevada-Cascades cordillera, separated from north-to-south just north of San Francisco Bay; and two east of the Sierra Nevada-Cascades cordillera, separated from east-to-west in the Great Basin desert. The branching pattern of populations suggests that populations south of the Transverse Ranges and west of the Sierra Nevada-Cascades cordillera are divergent from populations east of the Sierra Nevada-Cascades cordillera. The predominant mechanism of population divergence is allopatric divergence and contemporary secondary contact, which supports Quaternary glacial cycles as drivers of intraspecific genetic divergence. Chapter 2 builds on foundational work by Leaché et al. (2010) to characterize genetic and phenotypic clines along an elevation gradient in Yosemite National Park. At high elevations lizards are larger and more melanistic, while at low elevations lizards are smaller and lighter-colored. We sampled 78 individuals from a 21 km stretch of the Grand Canyon of the Tuolumne River in northern Yosemite. The elevation gradient spanned 1321 m from N Hetch Hetchy Reservoir (37.9168 N, 119.6595 W, 1167 m) in the west to E Glen Aulin (37.9076 N, 119.4196 W, 2488 m) in the east. We used 721 SNPs from ddRADseq to characterize genetic clines and estimate demographic history of populations along the elevation gradient. We found evidence for additional population structure and genetic divergence between phenotypically divergent individuals; one genetically distinct population corresponds to low elevation individuals and another corresponds to high elevation individuals. Analyses of SNPs, maximum size (snout-vent length, SVL), and coloration (ventral patch area) confirm that genes and phenotypes vary clinally, and not discretely, along the elevation gradient. Genetically distinct populations diverged in allopatry, but contemporary gene flow between populations is asymmetric. Genes flow uphill, with five times as many migrants entering the high elevation population from low elevation than the converse. Chapter 3 delves into the underlying sources of trait divergence between low and high elevation individuals from the Grand Canyon of the Tuolumne River elevation gradient. While low and high elevation lizards mature at the same age, high elevation lizards are larger and more melanistic than low elevation lizards. We disentangled the genetic and environmental constituents of phenotypic variation by rearing hatchling lizards under controlled lab conditions. We collected five gravid females from low elevation (N Hetch Hetchy Reservoir [37.96 N, -119.78 W, ca. 1200 m]) and eight gravid females from high elevation (Glen Aulin [37.91 N, -119.42 W, ca. 2400 m]), who produced 36 and 51 hatchling lizards, respectively. We evenly distributed hatchlings from both populations among two treatments that varied in potential activity time: short activity period (6 hrs) and long activity period (12 hrs). We varied activity time by limiting access to heat-lamp-produced thermal gradients, which are necessary for thermoregulation. We found evidence that differences in size are genetically-based; high elevation hatchlings were larger than low elevation hatchlings, regardless of treatment. We found evidence that differences in color are at least partially produced by phenotypic plasticity; high elevation hatchlings were capable of plastically lightening to a color that was lighter than low elevation hatchlings. We found evidence that differences in behavior are genetically-based; high elevation hatchlings spent more time engaged in active behaviors. Overall, our findings are suggestive of local adaptation of high elevation hatchlings to restricted activity periods at high elevation.