Landscape Influences on Dispersal of White-tailed Deer and Attendant Risk of Chronic Wasting Disease Spread as Assessed by a Landscape Genetics Approach PDF Download

Author: Krista Renee Lang
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Category :
Languages : en
Pages : 106

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Author: Amy C. Kelly
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Category :
Languages : en
Pages :

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In this study we used molecular techniques to examine deer movement and population structure in the context of chronic wasting disease transmission and spread. Chronic wasting disease is an infectious prion encephalopathy in cervids that is endemic to Colorado and Wyoming but has spread across the US within the last decade. Quantifying white-tailed deer movement and population structure in infected areas can facilitate predictions of CWD spread via deer dispersal. We analyzed microsatellite genotypes of white-tailed deer populations in southern Wisconsin and Illinois to quantify population level movements, genetic admixture and gender-biased dispersal patterns using FST and contingency tests. We also examined movements of individuals using assignment tests and spatial autocorrelation, and quantified dispersal events using parentage assignment. Finally, we compared genetic characteristics such as allelic diversity, heterozygosity and fixation indices between CWD infected and uninfected individuals to determine if CWD affects movement of white-tailed deer. Genetic characteristics were not different between CWD infected and uninfected deer, suggesting that changes in movement behaviors associated with clinical illness were not detectable with our molecular data. We found that both male and female deer move extensively in northern Illinois and southern Wisconsin, and that this movement could facilitate CWD spread via dispersal. In contrast, a few locations demonstrated reduced deer movement and female philopatry. One of these locations is a hotspot for CWD in Illinois, and it appears that reduced movements in this area could be exacerbating CWD transmission via direct contact among deer. The observed spatial heterogeneity in deer movement and population structure has important management implications as it allowed us to identify locations at risk for future CWD infection and areas in need of management. Our study was intented to guide population management and conservation, so we wanted to ensure that biological inferences were based on accurate genetic information. Therefore we identified sources of genotyping errors, evaluated measures to correct for their presence and provided recommendations to prevent their negative impacts. We detected null alleles in five of 13 previously evaluated microsatellites, and redesigned primers for two of these loci. Analytical corrections for null alleles were unable to fully prevent bias associated with these genotyping errors, and consequently, measures of population differentiation and kinship were negatively impacted. Our results demonstrate the importance of error evaluation during all stages of population studies, and emphasize the need to standardize procedures for genetic marker evaluation. Since chronic wasting disease management often involves decreasing deer densities to reduce the likelihood of disease occurrence and spread, we wanted to examine the genetic consequences of management in white-tailed deer herds. Increased removal of individuals can alter genetic characteristics of the population, cause a loss of genetic diversity, a decrease in fitness, or enable increased immigration. We compared allele frequencies among cohorts of deer to determine if culling changed the genetic composition of managed populations. Additionally, allele frequency distributions, heterozygosity, and genetic characteristics such as allelic richness and fixation indices were evaluated in pre- and post-cull deer populations to examine the effects of culling on effective population size, genetic differentiation and genetic diversity of white-tailed deer. Cohorts demonstrated little change in allele frequencies from year to year. However, evaluations of pre- and post-cull populations revealed increases in allelic richness and deficiencies in heterozygosity in post-cull populations, suggesting that these populations have received immigrants following intervention. Moreover, female deer, which tend to be philopatric, had significant changes in allele frequencies after culling was initiated. This study suggests that while reducing deer densities through culling enriches the genetic composition of deer, it could also result in immigration of CWD infected deer, and these potential ecological consequences need to be considered during the implementation of disease management plans. In this investigation, we also used landscape genetics to examine the effect of landscape features on dispersal and population boundaries of white-tailed deer. An awareness of how the landscape affects animal movement and genetic exchange between populations contributes to our understanding of wildlife ecology. By quantifying genetic structure across the landscape we have identified populations with high and low admixture and discovered gender specific barriers to deer movement that may contribute to CWD spread via dispersal. We found that rivers, streams and interstates contributed to the genetic structuring of females in the study area, but males were insensitive to these features. The observed variations in landscape use between males and females implies that CWD could spread via male movement relatively independently of natural and manmade landscape features, while CWD spread by females would occur over shorter distances because movement is inhibited by these landscape features. Certain genotypes of the prion gene (Prnp) have been shown to prolong disease progression and survival of CWD infected deer. Therefore, examining Prnp genotypes in CWD infected and uninfected deer populations can reveal associations between genotype and phenotype to determine if selective pressures are affecting Prnp allele frequencies. If selection is occurring, we would expect Prnp genotypes that prolong survival to be higher in infected populations compared to uninfected populations. To test this hypothesis, we sequenced Prnp of 219 (99 CWD positive and 120 CWD negative) deer from the CWD outbreak region of northern Illinois and southern Wisconsin. We also sampled deer from two uninfected populations: one ~150 km away from the outbreak region, and another ~300 km from the outbreak region. Twelve nucleotide polymorphisms, eight silent and four coding, were found in Prnp of the sampled populations. Five polymorphic loci had significantly different distributions of alleles between infected and uninfected individuals. Nucleotide base changes 60C/T, 285A/C, 286G/A, and 555C/T were observed with higher than expected frequencies in CWD negative animals suggesting disease resistance, while 153C/T was observed more than expected in positive animals, suggesting susceptibility. The total number of polymorphisms per animal, silent or coding, was negatively correlated to disease status. Polymorphisms 243T/A, 286G/A and 555C/T were found at higher than expected frequencies in uninfected populations. The total number of polymorphisms, both silent and coding, also differed between infected and uninfected populations. At the temporal scale examined, selection does not appear to be favoring genotypes associated with CWD resistance as these genotypes tended to have higher frequencies in uninfected populations. 0́3

Author: William Leroy Miller
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Category :
Languages : en
Pages :

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Wildlife diseases are important stressors of natural populations and commonly impact species of management and conservation interest. Because of this, mitigating the negative effects of these diseases is a common goal of many management strategies. One of the key goals in areas of recent disease emergence is to minimize the geographic diffusion of diseases across landscapes so that nave populations remain minimally impacted. Prospective tools for predicting disease flow are particularly helpful in the initial stages of the epizootic cycle. Evaluating patterns of population structure, susceptibility, and connectivity can provide important insights into the potential spread of diseases across landscapes. Landscape genetic analyses, in particular, have proven particularly useful in elucidating these population characteristics. Chronic wasting disease, a fatal neurodegenerative disease of members of the family Cervidae, is a disease of particular concern due to the ecological and economic importance of infected species. Chronic wasting disease is caused by an infectious prion protein that can be passed by contact among individuals and/or through the use of shared environments. Contact among nave and infected individuals is thought to play an important role in the geographic diffusion of this disease, and management plans commonly focus on minimizing contact among these groups. Population structure and patterns of gene flow impact the distribution and occurrence of chronic wasting disease on landscape where it occurs. Thus, assessing these factors may help to identify effective management units and to predict transmission patterns within and among populations. Additionally, individual and population susceptibility to this disease is modulated by genetic variability in the prion protein (PRNP) gene, so evaluating transmission dynamics in tandem with spatial PRNP variability provides a means of assessing the innate vulnerability of populations to disease occurrence and establishment.In this study, I evaluated the genetic structure of white-tailed deer (Odocoileus virginianus) in the Mid-Atlantic region of the United States of America in order to evaluate factors that may influence the epizootiology of chronic wasting disease. I used a panel of 11 microsatellite markers to assess spatial genetic structure and gene flow. These markers were chosen from a large suite of available loci (106 candidate markers) identified from 58 previous or ongoing studies of white-tailed deer genetics. These markers were chosen because they were characterized by low genotyping error rates and were inferred to be broadly applicable across the range of white-tailed deer in North America given the geographic distribution of previous studies. I genotyped a total of 2222 individuals to assess spatial genetic structure of white-tailed deer in the Mid-Atlantic region. White-tailed deer conformed to a pattern of isolation-by-distance at both fine and broad spatial scales. Despite this, 11 distinct subpopulation clusters were identified throughout the region. The edges of these subpopulations were associated with high-volume traffic roads and areas of greater elevational relief. Despite significant structure, subpopulations maintained high rates of connectivity. There was evidence of hierarchical genetic structure with the bounds of larger population units generally corresponding to physiographic provinces. Subpopulation units defined this way are more likely to be an effective disease management unit relative to those commonly defined by anthropocentric boundaries. Population structure is only one factor influencing the geographic distribution of diseases. Cervids are farmed in this region, and several captive cervid facilities have experienced recent outbreaks of chronic wasting disease. Egression from infected facilities represents another potential pathway for transmission. I used a Bayesian assignment algorithm to test for captive egression and dispersal events among free-ranging populations, both of which may contribute to epizootic patterns. I found a low (2.0%) but significant proportion of free-ranging deer that assigned to captive origin. Two deer that were infected with chronic wasting disease had a high probability of sourcing from captive populations. The proportion of individuals that assigned to a migratory origin was as high as 13.8% among the four subsampling units, and the proportion of individuals with admixed ancestry was as high as 46.7%. This suggests dispersal is common and ongoing and is commensurate with the high migration rates reported previously. One deer infected with chronic wasting disease assigned to a migratory origin. These results may indicate that both captive egression and natural dispersal have the potential to contribute to the spread of this disease into previously uninfected regions.Individual susceptibility to chronic wasting disease is thought to be linked to variation at two single nucleotide polymorphisms in the PRNP gene. Thus, population-scale variability at these loci may influence the risk of infection and establishment. The Mid-Atlantic populations of white-tailed deer generally had a higher proportion of susceptible individuals relative to populations with a longer history of chronic wasting disease. Variability at these loci varied spatially within the region and generally conformed to patterns of population structure. This suggests that some populations may be more innately susceptible than others to chronic wasting disease establishment. Understanding patterns of population structure and susceptibility provides insights into the potential occurrence of chronic wasting disease but does not necessarily explain transmission dynamics among populations. Transmission is expected to be facilitated by dispersal, but how deer move among populations is likely a consequence of the underlying landscape matrix. I evaluated the correlation between landscape features and patterns of gene flow using a resistance surface modeling approach to identify potential transmission corridors. Patterns of genetic differentiation were best explained by a resistance surface including percent forest cover, elevational relief, and traffic volume. While large streams were also included in the resistance surface, landscape resistance related to streams was negligible. Elevational relief and traffic volume were less resistant features than areas of low forest cover, highlighting the permeability of these features to deer movement. Gene flow was facilitated through forested corridors in heterogeneous landscapes and was more diffuse in homogeneous landscapes. A large number of chronic wasting disease cases occurred in areas of high connectivity, indicating that these areas may influence disease transmission among distinct groups of deer. In conclusion, patterns of white-tailed deer genetic structure are cryptic and associated with features that are permeable to movement. Nevertheless, these features may influence the distribution of chronic wasting disease and the possibility for transmission among populations. Furthermore, spatial variability at loci associated with disease susceptibility suggests that some populations may be more innately at risk for disease establishment than others. Incorporating the inferred patterns of population structure, connectivity, and susceptibility into disease forecasting models represents a logical extension and may further elucidate the trends observed here. Other sources of infection, such as captive egression, may pose a risk independent of patterns predicted by natural population structure. Thus, joint consideration of anthropogenic and natural sources of infection may further aid in predicting future epizootic patterns.

Author: Iowa State University
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Category : Commencement ceremonies
Languages : en
Pages : 124

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Author: Stacie Joy Robinson
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ISBN:
Category :
Languages : en
Pages : 133

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Author: Lesa H. Skuldt
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ISBN:
Category :
Languages : en
Pages : 310

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Author: Jonathan David Cook
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Category : Electronic dissertations
Languages : en
Pages : 153

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Chronic wasting disease (CWD) is a transmissible spongiform encephalopathy that has spread in North American cervids for at least the last 50 years. Since its initial discovery in Colorado in 1967 (Williams and Young 1980), it has affected at least eight cervid species including white-tailed deer (Odocoileus virginianus), spread to at least 26 U.S. states (Rivera et al. 2019), and been called the greatest contemporary threat to free-ranging deer herds (Gillin and Mawdsley 2018). Once CWD is introduced, it is known to cause localized population declines that threaten the long-term sustainability of deer herds and associated hunting activities. As a result, state and federal agencies have allocated a large amount of financial and staff-time resources to manage CWD but have experienced limited success.One of the most rational and effective ways to mitigate the effects of a persistent disease like CWD is to perform proactive surveillance efforts that can either prevent, or detect and eradicate, disease prior to its establishment. However, a combination of human activities that increase the risk of disease translocation, complex disease dynamics, and imperfect observation makes assessing the comprehensive risk of CWD introduction by empirical study prohibitive. Furthermore, once CWD is introduced and becomes established it has been difficult to maintain long-term monitoring programs at a level that produces accurate spatial predictions and improves our ability to understand the causal mechanisms that promote disease spread and persistence.I developed several distinct modeling approaches to perform proactive and reactive CWD surveillance and monitoring given limitations in data availability, disease observation, and long-term financial and staff-time resources. I determined that expert elicitation techniques are valuable tools to help inform comprehensive risk assessments given that appropriate methods are employed to limit expert biases. I determined that increasing the complexity of disease models can help predict the locations of CWD occurrence and may elucidate mechanisms that promote localized spread, long-distance spread, and persistence of disease. Finally, I utilized important covariate relationships that impact disease detection to help inform the strategic and efficient long-term use of resources. Important findings from my dissertation include: 1) a comprehensive approach to estimate the spatially-explicit risk of disease exposure and amplification that is adaptable to localized disease hazards; 2) CWD extent estimates that are specific to the localized landscape and that include more disease detections than existing distance benchmark approaches; 3) a statistical modeling framework that incorporates more of the complex disease ecology and produces more accurate spatial estimates of disease occurrence; and finally, 4) the estimation of important covariate relationships that affect disease spread and persistence as well as disease detection. This dissertation and associated research findings will be broadly useful to disease management endeavors and contribute to improved decision making that maximizes the value of resources spent to acquire and learn from disease observation data.

Author: David R. Edmunds
Publisher:
ISBN: 9780549795223
Category : Chronic wasting disease
Languages : en
Pages : 120

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Author:
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Category : Boone County (Iowa)
Languages : en
Pages : 557

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Author: Daniel J. Storm
Publisher:
ISBN:
Category :
Languages : en
Pages : 87

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