Landscape genetics
Landscape genetics is the scientific discipline that combines
Landscape genetics differs from the fields of
History
Landscape genetics emerged as its own
Advances and applications
Landscape genetics has advanced ecological and evolutionary theory by facilitating an understanding of how gene flow and adaptation occur in real heterogeneous landscapes. It has also allowed for the estimation of functional connectivity across landscapes.[4] Elucidating landscape features that act as barriers or facilitators of dispersal can inform the construction or preservation of wildlife corridors that connect fragmented landscapes. Landscape genetics can also help predict how diseases will spread across a landscape or how proposed management actions will affect populations. Finally, landscape genetics can help predict how well populations will adapt to continuing global change.[2]
Methods
Genetic markers
Molecular markers of genetic diversity such as DNA microsatellites, mitochondrial DNA, amplified fragment length polymorphisms, and alloenzymes are tested in random individuals of a particular species across a landscape.[2] These markers are used to determine the genotype (genetic make-up) of the individuals tested.
Landscape and environmental features
Landscape features include
Statistical tools
Identifying genetic patterns
Various statistical tools are utilized to identify genetic patterns from the genetic markers collected. Methods that cluster individuals into subpopulations based on genetic differentiation or distance, such as fixation index (FST) and Bayesian assignment methods, are often used. However, because individuals are sometimes evenly distributed rather than spatially clustered across a landscape, these methods are limited and alternative methods are being developed.[2]
Correlating genetic patterns to landscape
Statistical tools such as the
Example
A study published in 2012[7] analyzed the landscape genetics of white tail deer in Wisconsin and Illinois. They extracted DNA from the lymph nodes of 2,069 harvested deer across 64 townships. Fifteen microsatellite markers were used for genotyping. A Bayesian population assignment test found no distinct subpopulations based on the genetic data. Correlograms were used to elucidate fine-scale social structure, and found that more heavily forested and fragmented townships had more genetic relatedness between individual deer. Spatial principal component analysis was used to elucidate broad-scale population connectivity. Partial Mantel tests found a correlation between genetic distance and geographic barriers, particularly roads and rivers. However, these were not absolute barriers and did not divide the deer into distinct subpopulations.
The finding of high genetic connectivity among the sampled deer has management implications for the setting of harvest number and population goals. The finding of high genetic connectivity also has implications for the spread of chronic wasting disease among deer.
Sub-disciplines
Seascape genetics
Seascape genetics is a sub discipline of landscape genomics that scientists started to use in 2006.[8] The emergence of this field proceeded landscape genetics, advances in genetic laboratory technology, and higher resolution marine environmental data.[9] Like landscape genetics, seascape genetics is a multidisciplinary field. Areas of expertise used in sea scape genetics includes oceanography, ecology, and population genetics.[8][10] Seascapes differ from landscapes due to differential connectivity in the aquatic environment. Currents allow for increased connectivity in some locations and restrict connectivity elsewhere. Many organisms that live in the ocean rely on currents to move their gametes and larvae which is called dispersal. Variable dispersal availability leads to subpopulations that have different structure; therefore, subpopulations are exposed to distinct selective pressures, experience separate rates of drift and have unique genetic diversity.[11]
Seascape genomics is a tool that utilizes genetic markers in tandem with current patterns to better understand dispersal. Another key difference when studying marine systems is that many animals have extremely large population sizes. Substantial population sizes in the marine setting allows for greater adaptive potential with larger effective population size,[12] meaning the portion of the population that is reproducing and passing along genes increases. A large population will have greater influence from selection than drift, thus marine organisms are more likely to have greater levels of local adaptation. In seascape analyses, genetic data allows for greater species understanding and tracking when the full life history is unknown or unable to be studied with ecology.[1] Population genetics incorporates many theories and techniques, all of which need to be taken into consideration for seascape and landscape analyses. There are several ways to collect genetic information. Popular methods in seascape genetics have been single nucleotide polymorphisms (SNPs), mitochondrial DNA, random amplified polymorphic DNAs, microsatellites, allozymes, and full genomes.[2] Collecting and processing sufficient samples has been a time-consuming process in the past. Next generation sequencing has helped to expand the field of landscape genomics because it allows for rapid sequencing of extremely large genomes.[13]
Seascape genomics can be applied marine life with varying life histories to answer various questions about genetic influences on population dynamics. Analyzes on sessile organisms, animals such as clams that stay in the same place their whole life, can easily be analyzed to better understand environmental evolutionary pressures. One example, Salmoni et at[14] used environmental data and genetic analysis to identify a heat tolerant gene in corals. Many other studies have been done on organisms such as oysters,[15] seagrass,[16] and mussels.[17] Motile animals, animals that can move around, have also been studies through seascape genomics. DiBattista and his team[18] studied how hydrodynamics influences snapper larval disbursement and were able to characterize connectivity between populations. Studies that utilize seascape genomics can be used in conservation and restoration efforts. This type of studies can help to define resilient individuals or classify areas that would be best for marine protected area due to their ecological purpose.
Landscape genomics
Landscape genomics also correlates genetic data with landscape data, but the genetic data comes from multiple loci (locations on a chromosome) across the genome of the organism, as in population genomics. Landscape genetics typically measures less than a dozen different microsatellites in an organism, while landscape genomics often measures single nucleotide polymorphisms at thousands of loci.[19] This allows for the identification of outlier loci that may be under selection. Correlation to landscape data allows for identification of landscape factors contributing to genetic adaptation. This field is growing due to advances in next-generation sequencing techniques.[4]
Pitfalls
As a new and fast growing interdisciplinary field with no explicitly identified best practices, it has been subject to a number of flaws in both study design and interpretation.[20] A 2016 publication[2] identified four common pitfalls of landscape genetics research that should be targeted for correction. These include assuming gene flow is always advantageous, over-generalizing results, failing to consider other processes that affect the genetic structure of populations, and mistaking quantitative methods for robust study design.[20] In particular, authors have been encouraged to report their sampling design, reproducibility of molecular data, and details on the spatial data set and spatial analyses utilized.[2] Because the effects of landscape on gene flow are not universal, sweeping generalities cannot be made, and species-specific studies are necessary.[2]
Many of these pitfalls result from the interdisciplinary nature of landscape genetics, and could be avoided with better collaboration among specialists in the fields of population genetics, landscape ecology, spatial statistics, and geography.[6]
References
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