Your search keyword '"noninvasive genetic sampling"' showing total 3 results

1. Genetic and genomic monitoring with minimally invasive sampling methods.

Author

Carroll, Emma L., Bruford, Mike W., DeWoody, J. Andrew, Leroy, Gregoire, Strand, Alan, Waits, Lisette, and Wang, Jinliang

Subjects

*MOLECULAR ecology, *GENOMICS, *INTRODUCED species, *CONSERVATION biology, *POPULATION biology

Abstract

Abstract: The decreasing cost and increasing scope and power of emerging genomic technologies are reshaping the field of molecular ecology. However, many modern genomic approaches (e.g., RAD‐seq) require large amounts of high‐quality template DNA. This poses a problem for an active branch of conservation biology: genetic monitoring using minimally invasive sampling (MIS) methods. Without handling or even observing an animal, MIS methods (e.g., collection of hair, skin, faeces) can provide genetic information on individuals or populations. Such samples typically yield low‐quality and/or quantities of DNA, restricting the type of molecular methods that can be used. Despite this limitation, genetic monitoring using MIS is an effective tool for estimating population demographic parameters and monitoring genetic diversity in natural populations. Genetic monitoring is likely to become more important in the future as many natural populations are undergoing anthropogenically driven declines, which are unlikely to abate without intensive adaptive management efforts that often include MIS approaches. Here, we profile the expanding suite of genomic methods and platforms compatible with producing genotypes from MIS, considering factors such as development costs and error rates. We evaluate how powerful new approaches will enhance our ability to investigate questions typically answered using genetic monitoring, such as estimating abundance, genetic structure and relatedness. As the field is in a period of unusually rapid transition, we also highlight the importance of legacy data sets and recommend how to address the challenges of moving between traditional and next‐generation genetic monitoring platforms. Finally, we consider how genetic monitoring could move beyond genotypes in the future. For example, assessing microbiomes or epigenetic markers could provide a greater understanding of the relationship between individuals and their environment. [ABSTRACT FROM AUTHOR]

Published

2018

2. Describing a developing hybrid zone between red wolves and coyotes in eastern North Carolina, USA.

Author

Bohling, Justin H., Dellinger, Justin, McVey, Justin M., Cobb, David T., Moorman, Christopher E., and Waits, Lisette P.

Subjects

*HYBRID zones, *LIFE zones, *COYOTE, *SPECIES hybridization, *MICROSATELLITE repeats

Abstract

When hybridizing species come into contact, understanding the processes that regulate their interactions can help predict the future outcome of the system. This is especially relevant in conservation situations where human activities can influence hybridization dynamics. We investigated a developing hybrid zone between red wolves and coyotes in North Carolina, USA to elucidate patterns of hybridization in a system heavily managed for preservation of the red wolf genome. Using noninvasive genetic sampling of scat, we surveyed a 2880 km2 region adjacent to the Red Wolf Experimental Population Area ( RWEPA). We combined microsatellite genotypes collected from this survey with those from companion studies conducted both within and outside the RWEPA to describe the gradient of red wolf ancestry. A total of 311 individuals were genotyped at 17 loci and red wolf ancestry decreased along an east-west gradient across the RWEPA. No red wolves were found outside the RWEPA, yet half of individuals found within this area were coyotes. Hybrids composed only 4% of individuals within this landscape despite co-occurrence of the two species throughout the RWEPA. The low proportion of hybrids suggests that a combination of active management and natural isolating mechanisms may be limiting intermixing within this hybrid system. [ABSTRACT FROM AUTHOR]

Published

2016

3. Describing a developing hybrid zone between red wolves and coyotes in eastern North Carolina,<scp>USA</scp>

Author

Justin M. McVey, Lisette P. Waits, Christopher E. Moorman, Justin A. Dellinger, David T. Cobb, and Justin H. Bohling

Subjects

0106 biological sciences, 0301 basic medicine, Population, Endangered species, Introgression, Biology, 010603 evolutionary biology, 01 natural sciences, genetic introgression, 03 medical and health sciences, Conservation reliant species, Hybrid zone, genetic cline, Genetics, education, Ecology, Evolution, Behavior and Systematics, Hybrid, education.field_of_study, noninvasive genetic sampling, Ecology, Original Articles, endangered species, Limiting, 030104 developmental biology, conservation‐reliant species, Microsatellite, Original Article, General Agricultural and Biological Sciences

Abstract

When hybridizing species come into contact, understanding the processes that regulate their interactions can help predict the future outcome of the system. This is especially relevant in conservation situations where human activities can influence hybridization dynamics. We investigated a developing hybrid zone between red wolves and coyotes in North Carolina, USA to elucidate patterns of hybridization in a system heavily managed for preservation of the red wolf genome. Using noninvasive genetic sampling of scat, we surveyed a 2880 km2 region adjacent to the Red Wolf Experimental Population Area (RWEPA). We combined microsatellite genotypes collected from this survey with those from companion studies conducted both within and outside the RWEPA to describe the gradient of red wolf ancestry. A total of 311 individuals were genotyped at 17 loci and red wolf ancestry decreased along an east–west gradient across the RWEPA. No red wolves were found outside the RWEPA, yet half of individuals found within this area were coyotes. Hybrids composed only 4% of individuals within this landscape despite co‐occurrence of the two species throughout the RWEPA. The low proportion of hybrids suggests that a combination of active management and natural isolating mechanisms may be limiting intermixing within this hybrid system.

Published

2016