Space is the Place: Effects of Continuous Spatial Structure on Analysis of Population Genetic Data

Battey, C. J.; Ralph, Peter L.; Kern, Andrew D.

doi:10.1534/genetics.120.303143

Cited by 100 publications

(114 citation statements)

References 112 publications

(131 reference statements)

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“…We first evaluated our method on genotypes from populations simulated by SLiM v3 (Haller and Messer, 2019), using the model of continuous space described in Battey et al (2019). We simulated a 50 × 50 unit square landscape with expected density ( d ) of 5 individuals per unit area, resulting in census sizes of around 12,500.…”

Section: Methodsmentioning

confidence: 99%

Predicting Geographic Location from Genetic Variation with Deep Neural Networks

Battey

Ralph

Kern

2019

Preprint

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6Most organisms are more closely related to nearby than distant members of their species, creating 7 spatial autocorrelations in genetic data. This allows us to predict the location of origin of a genetic 8 sample by comparing it to a set of samples of known geographic origin. Here we describe a deep 9 learning method, which we call Locator, to accomplish this task faster and more accurately than 10 existing approaches. In simulations, Locator infers sample location to within 4.1 generations of 11 dispersal and runs at least an order of magnitude faster than a recent model-based approach. 12 We leverage Locator's computational efficiency to predict locations separately in windows across 13 the genome, which allows us to both quantify uncertainty and describe the mosaic ancestry and 14 patterns of geographic mixing that characterize many populations. Applied to whole-genome 15 sequence data from Plasmodium parasites, Anopheles mosquitoes, and global human populations, 16 this approach yields median test errors of 16.9km, 5.7km, and 85km, respectively. 17 Introduction 18In natural populations, local mate selection and dispersal create correlations between geographic 19 location and genetic variation -each individual's genome is a mosaic of material inherited from 20 recent ancestors that are usually geographically nearby. Given a set of genotyped individuals of 21 known geographic provenance, it is therefore possible to predict the location of new samples from 22 genetic information alone (Guillot et al., 2015; Yang et al., 2012; Wasser et al., 2004; Rañola et al., 23 2014; Bhaskar et al., 2016; Baran et al., 2013). This task has forensic applications -for example, 24 estimating the location of trafficked elephant ivory as in Wasser et al. (2004) -and also offers a way 25 to analyze variation in geographic ancestry without assuming the existence of discrete ancestral 26 populations. 27The most common approaches to estimating sample locations are based on unsupervised geno-28 type clustering or dimensionality reduction techniques. Genetic data from samples of both known 29 and unknown origin are jointly analyzed, and unknown samples are assigned to the location of 30 known individuals with which they share a genotype cluster or region of PC space (Breidenbach 31 et al., 2019; Battey et al., 2018; Cong et al., 2019). However, these methods require an additional 32 mapping from genotype clusters or PC space to geography, and can produce nonsensical results if 33 unknown samples are hybrids or do not originate from any of the sampled reference populations. 34Existing methods for estimating sample location that explicitly model continuous landscapes 35 use a two-step procedure. A smoothed map describing variation in allele frequencies over space 36 1 Battey et al. 2019Locator is first estimated for each allele based on the genotypes of individuals with known locations, and 37 locations of new samples are then predicted by maximizing the likelihood of observing a given 38 combination of alleles at the p...

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Section: Methodsmentioning

confidence: 99%

Predicting Geographic Location from Genetic Variation with Deep Neural Networks

Battey

Ralph

Kern

2019

Preprint

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“…Direct measurement of dispersal in natural populations is often difficult or impossible due to practical difficulties in tracking large numbers of individuals over long periods of time. It is often more feasible to instead infer dispersal from spatial patterns of genetic diversity [Cayuela et al, 2018, Bradburd and Ralph, 2019, Battey et al, 2020. Populations with limited dispersal should exhibit "isolation by distance": the more distant individuals are from each other in space, the less related they tend to be [Wright, 1946, Rohlf and Schnell, 1971, Slatkin, 1991.…”

Section: Introductionmentioning

confidence: 99%

Isolation by Distance in Populations with Power-law Dispersal

2020

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Limited dispersal results in isolation by distance in spatially structured populations, in which individuals found further apart tend to be less related to each other. Models of populations undergoing short-range dispersal predict a close relation between the distance individuals disperse and the length scale over which two sampled individuals are likely to be closely related. In this work, we study the effect of long jumps on patterns of isolation by distance by replacing the typical short-range dispersal kernel with a long-range, power-law kernel. We find that incorporating long jumps leads to a slower decay of relatedness with distance, and that the quantitative form of this slow decay contains visible signatures of the underlying dispersal process. K 1 (y|t) = 1 2π ∞ −∞ dk exp (−iky − D α t|k| α ) .(1)

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“…These clusters are, however, an approximation of a very complex genealogical process. Indeed, the clusters cannot be seen as discrete, originally isolated populations, as there may be both isolation-by-distance and hierarchical population structure within each of these groups (Frantz et al, 2009;Janes et al, 2017;Battey, Ralph, and Kern, 2019). The clusters themselves are also the result of more complex admixture and migration events that occurred before the Holocene (Fu et al, 2016).…”

Section: Discussionmentioning

confidence: 99%

A geostatistical approach to modelling human Holocene migrations in Europe using ancient DNA

Racimo

Woodbridge

Fyfe

et al. 2019

Preprint

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The European continent was subject to two major migrations of peoples during the Holocene: the northwestward movement of Anatolian farmer populations during the Neolithic and the westward movement of Yamnaya steppe peoples during the Bronze Age. These movements changed the genetic composition of the continent's inhabitants, via admixture and population replacement processes. The Holocene was also characterized by major changes in vegetation composition, which altered the environment occupied by the original hunter-gatherer populations. Here, we use a combination of paleogenomics and geostatistical modelling to produce detailed maps of the movement of these populations over time and space, and to understand how these movements impacted the European vegetation landscape. We find that the dilution of hunter-gatherer ancestries and the Yamnaya steppe migration coincided with a reduction in the amount of broad-leaf forest and an increase in the amount of pasture lands in the continent. We also show that climate played a role in these vegetational changes. Additionally, we find that the spread of Neolithic farmer ancestry had a two-pronged wavefront, in agreement with similar findings based on patterns of the cultural spread of farming from radiocarbon-dated archaeological sites. With thousands of ancient genomes publicly available and in production, we foresee that the integration of ancient DNA with geostatistical techniques and large-scale archaeological datasets will revolutionize the study of ancient populations movements, and their effects on local fauna and flora.

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Space is the Place: Effects of Continuous Spatial Structure on Analysis of Population Genetic Data

Cited by 100 publications

References 112 publications

Predicting Geographic Location from Genetic Variation with Deep Neural Networks

Predicting Geographic Location from Genetic Variation with Deep Neural Networks

Isolation by Distance in Populations with Power-law Dispersal

A geostatistical approach to modelling human Holocene migrations in Europe using ancient DNA

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