Your search keyword '"Miller-Butterworth C"' showing total 6 results

1. Genetic Structure of Little Brown Bats (Myotis lucifugus) Corresponds with Spread of White-Nose Syndrome among Hibernacula

Author

Miller-Butterworth, C. M., primary, Vonhof, M. J., additional, Rosenstern, J., additional, Turner, G. G., additional, and Russell, A. L., additional

Published

2014

2. Contrasting genetic structure in two co-distributed species of old world fruit bat

Author

Chen, J, Rossiter, SJ, Flanders, JR, Sun, Y, Hua, P, Miller-Butterworth, C, Liu, X, Rajan, KE, Zhang, S, Chen, J, Rossiter, SJ, Flanders, JR, Sun, Y, Hua, P, Miller-Butterworth, C, Liu, X, Rajan, KE, and Zhang, S

Abstract

The fulvous fruit bat (Rousettus leschenaulti) and the greater short-nosed fruit bat (Cynopterus sphinx) are two abundant and widely co-distributed Old World fruit bats in Southeast and East Asia. The former species forms large colonies in caves while the latter roots in small groups in trees. To test whether these differences in social organization and roosting ecology are associated with contrasting patterns of gene flow, we used mtDNA and nuclear loci to characterize population genetic subdivision and phylogeographic histories in both species sampled from China, Vietnam and India. Our analyses from R. leschenaulti using both types of marker revealed little evidence of genetic structure across the study region. On the other hand, C. sphinx showed significant genetic mtDNA differentiation between the samples from India compared with China and Vietnam, as well as greater structuring of microsatellite genotypes within China. Demographic analyses indicated signatures of past rapid population expansion in both taxa, with more recent demographic growth in C. sphinx. Therefore, the relative genetic homogeneity in R. leschenaulti is unlikely to reflect past events. Instead we suggest that the absence of substructure in R. leschenaulti is a consequence of higher levels of gene flow among colonies, and that greater vagility in this species is an adaptation associated with cave roosting. © 2010 Chen et al.

Published

2010

3. Sequence Variation in the Primate Dopamine Transporter Gene and Its Relationship to Social Dominance

Author

Miller-Butterworth, C. M., primary, Kaplan, J. R., additional, Shaffer, J., additional, Devlin, B., additional, Manuck, S. B., additional, and Ferrell, R. E., additional

Published

2007

4. Identification and evaluation of a core microsatellite panel for use in white-tailed deer (Odocoileus virginianus).

Author

Miller WL, Edson J, Pietrandrea P, Miller-Butterworth C, and Walter WD

Subjects

Alleles, Animals, Genetic Variation, Genotype, Quantitative Trait Loci, United States, Deer genetics, Evolution, Molecular, Microsatellite Repeats

Abstract

Background: Microsatellite loci have been used extensively over the past two decades to study the genetic characteristics of non-model species. The ease of microsatellite development and ability to adapt markers from related species has led to the proliferation of available markers for many commonly studied species. Because it is often infeasible to genotype individuals across all available loci, researchers generally rely on subsets of markers. Marker choice can bias inferences made using disparate suites of loci. This has been a primary motivation for efforts to identify uniform marker panels. Here, we use the geographic distribution of previous studies to identify microsatellite loci for white-tailed deer (Odocoileus virginianus) with the potential for widespread use, and we evaluate the effectiveness of this panel in a portion of the range where few previous studies have been conducted. The purpose was to consolidate the numerous genetic resources for this species into a manageable panel and to provide a uniform methodology that improves comparisons between past and future studies., Results: We reviewed microsatellite panels from 58 previous or ongoing projects and identified 106 candidate loci. We developed a multiplex protocol and evaluated the efficacy of 17 of the most commonly used loci using 720 DNA samples collected from the Mid-Atlantic region of the United States of America. Amplification errors were detected in six of these loci. The 11 remaining loci were highly polymorphic, exhibited low frequencies of null alleles, and were easy to interpret with the aid of allele binning software., Conclusions: The development of broadly-applicable, core microsatellite panels has the potential to improve repeatability and comparative ability for commonly studied species. The properties of the consolidated 11 microsatellite panel suggest that they are applicable for many common research objectives for white-tailed deer. The geographic distribution of previous studies using these markers provides a greater degree of confidence regarding the robustness to common sources of error related to amplification anomalies, such as null alleles, relative to loci with more limited use. While this does not replace further evaluation of genotyping errors, it does provide a common platform that benefits future research studies.

Published

2019

5. Population and genetic outcomes 20 years after reintroducing bobcats (Lynx rufus) to Cumberland Island, Georgia USA.

Author

Diefenbach D, Hansen L, Bohling J, and Miller-Butterworth C

Abstract

In 1988-1989, 32 bobcats Lynx rufus were reintroduced to Cumberland Island (CUIS), Georgia, USA, from which they had previously been extirpated. They were monitored intensively for 3 years immediately post-reintroduction, but no estimation of the size or genetic diversity of the population had been conducted in over 20 years since reintroduction. We returned to CUIS in 2012 to estimate abundance and effective population size of the present-day population, as well as to quantify genetic diversity and inbreeding. We amplified 12 nuclear microsatellite loci from DNA isolated from scats to establish genetic profiles to identify individuals. We used spatially explicit capture-recapture population estimation to estimate abundance. From nine unique genetic profiles, we estimate a population size of 14.4 (SE = 3.052) bobcats, with an effective population size (N e) of 5-8 breeding individuals. This is consistent with predictions of a population viability analysis conducted at the time of reintroduction, which estimated the population would average 12-13 bobcats after 10 years. We identified several pairs of related bobcats (parent-offspring and full siblings), but ~75% of the pairwise comparisons were typical of unrelated individuals, and only one individual appeared inbred. Despite the small population size and other indications that it has likely experienced a genetic bottleneck, levels of genetic diversity in the CUIS bobcat population remain high compared to other mammalian carnivores. The reintroduction of bobcats to CUIS provides an opportunity to study changes in genetic diversity in an insular population without risk to this common species. Opportunities for natural immigration to the island are limited; therefore, continued monitoring and supplemental bobcat reintroductions could be used to evaluate the effect of different management strategies to maintain genetic diversity and population viability. The successful reintroduction and maintenance of a bobcat population on CUIS illustrates the suitability of translocation as a management tool for re-establishing felid populations.

Published

2015

6. Contrasting genetic structure in two co-distributed species of old world fruit bat.

Author

Chen J, Rossiter SJ, Flanders JR, Sun Y, Hua P, Miller-Butterworth C, Liu X, Rajan KE, and Zhang S

Subjects

Analysis of Variance, Animals, China, Chiroptera classification, Cluster Analysis, Cytochromes b genetics, DNA, Mitochondrial chemistry, DNA, Mitochondrial genetics, Genotype, Geography, Haplotypes, India, Microsatellite Repeats genetics, Molecular Sequence Data, Phylogeny, Sequence Analysis, DNA, Species Specificity, Vietnam, Biodiversity, Chiroptera genetics, Chiroptera growth & development, Genetic Variation

Abstract

The fulvous fruit bat (Rousettus leschenaulti) and the greater short-nosed fruit bat (Cynopterus sphinx) are two abundant and widely co-distributed Old World fruit bats in Southeast and East Asia. The former species forms large colonies in caves while the latter roots in small groups in trees. To test whether these differences in social organization and roosting ecology are associated with contrasting patterns of gene flow, we used mtDNA and nuclear loci to characterize population genetic subdivision and phylogeographic histories in both species sampled from China, Vietnam and India. Our analyses from R. leschenaulti using both types of marker revealed little evidence of genetic structure across the study region. On the other hand, C. sphinx showed significant genetic mtDNA differentiation between the samples from India compared with China and Vietnam, as well as greater structuring of microsatellite genotypes within China. Demographic analyses indicated signatures of past rapid population expansion in both taxa, with more recent demographic growth in C. sphinx. Therefore, the relative genetic homogeneity in R. leschenaulti is unlikely to reflect past events. Instead we suggest that the absence of substructure in R. leschenaulti is a consequence of higher levels of gene flow among colonies, and that greater vagility in this species is an adaptation associated with cave roosting.

Published

2010