Moment equations for D and D².

Enumerating possible copying, recombination, and mutation events for two lineages also leads to a well-known recursion for [13]. The possibility of sharing a common parent from the previous generation leads to the same decay familiar from Eq 1. also decays due to recombination with rate proportional to the probability r of a recombination event between two loci in a given generation. Throughout, we assume r ≪ 1, so that higher order terms may be ignored. For loosely linked or unlinked linked loci (r = 1/2), higher order terms must be considered [14].

To leading order in r, u, and , we have (2) Mutation doesn’t contribute to because any mutation event is equally likely to contribute positively or negatively to the statistic. As a result, D is expected to be zero across the genome.

However, the second moment is positive. Hill and Robertson [14] found a recursion for a triplet of statistics including , which we write as where p is the allele frequency of A, and q is the allele frequency of B. The recursion is (3) where and are matrix operators for drift and recombination, respectively. To leading order in and r, these take the form and

The three statistics in the Hill-Robertson system have a natural interpretation. is the variance of D and has received plenty of attention over the years. The second statistic includes a term z = (1 − 2p)(1 − 2q) whose magnitude is largest when there are rare alleles at both loci, and which is positive when p and q both correspond to the minor allele (or both to the major allele). Thus measures positive covariance among low frequency variants. Fig 2A–2C shows that the decay of and are sensitive to demographic history. Fig A2 in S1 Appendix shows how the bulk of the Dz statistic is contributed by pairs of variants where the rarest allele has frequency between 2 and 20%, while common variants comprises the bulk of D².

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Fig 2. LD curves are sensitive to demography.

Demographic histories shown in (A) affect statistics in the Hill-Robertson system and their dependance on recombination distance (B-C). Both the amplitude and shape of the LD curves differ between demographic models for (B) and (C) . (D) To illustrate the effect of admixture on LD curves, we consider two populations in isolation for 2N generations, followed by an admixture event where the focal population receives 1% of lineages from the diverged population. (E) curves are largely unaffected by this low level of admixture. (F) However, is immediately and strongly elevated following admixture, and remains significantly elevated for prolonged time T (in units of 2N generations) since the admixture event.

https://doi.org/10.1371/journal.pgen.1008204.g002

is the joint heterozygosity across pairs of SNPs. If we sample four haplotypes from the population, this is proportional to the probability that the first pair differ at the left locus, and the second pair differ at the right locus.

The applications in this article focus on generalizing the Hill-Robertson equations to multi-population settings. However, we first outline generalizations to high-order moments and non-neutral evolution, leaving theoretical developments and simulations to the Appendix.

Generalizing to higher moments of D.

The existence of tractable higher-order moment equations for one-locus statistics [3] suggests the existence of a similar high-order system for two-locus statistics. Higher moments of D provide additional information about the distribution of two-locus haplotypes. Appendix S1.1 shows that the Hill-Robertson system can be extended to compute any moment of D, and presents recursions for those systems of arbitrary order D^m that closes under drift, recombination, and mutation.

This family of recursion equations takes a form similar to the D² system: the evolution of requires and , with each of those terms depending on additional terms of the same order and smaller orders (Fig 1). For any order m, Appendix S1.4.1 shows the system closes and forms a hierarchy of moment equations, in that the D^m recursion contains the D^m−2 system, which itself contains the D^m−4 system, and so on (Fig A1 in S1 Appendix). Just as the Wright equation for heterozygosity generalizes naturally to equations for the more informative distribution of allele frequency [3], the Hill and Robertson equations for and generalize to informative higher-order LD statistics.

Generalizing to arbitrary two-locus haplotype distribution.

Given the analogy between the frequency spectrum and the Hill-Robertson equations, it is natural to study the connection between the moment equations for and the evolution of the two-locus haplotype frequency distribution Ψ_n(f_AB, f_Ab, f_aB, f_ab).

While classical approaches for computing Ψ_n [18, 20] were limited to neutrality and steady-state demography, recent coalescent and diffusion developments allow for Ψ_n to be computed under non-equilibrium demography and selection [8, 23]. These approaches are computationally expensive and limited to one population, as Ψ_n has size , and the P-population distribution grows asymptotically as n^3P.

Generalizing the approach of Jouganous et al. [3], we can write a recursion equation on the entries of Ψ_n under drift, mutation, recombination, and selection at one or both loci (Appendix S1.3). As expected, this recursion does not close under selection: to find Ψ_n at time t + 1, we require Ψ_n+1 and Ψ_n+2 at time t. It also does not close under recombination, requiring a closure approximation. Using the same closure strategy for selection and recombination, however, we can approximate the entries of Ψ_n+1 and Ψ_n+2 as linear combinations of entries in Ψ_n and obtain a closed equation. This approach provides accurate approximation for moderate n under recombination and selection (Appendix S1.3.5) that represent a 10 to 100-fold speedup over the numerical PDE implementation in [23] (Table A1 in S1 Appendix). However, closure is inaccurate for small n.

By contrast to the full two-locus model, equations for moments of D close under recombination because the symmetric combination of haplotype frequencies that define D ensures the cancellation of higher-order terms (Appendix S1.1.2). This makes the moments of D particularly suitable for rapid computation of low-order statistics over a large number of populations.

The Hill-Robertson system does not close, however, if one or both loci are under selection. Appendix S1.1.4 considers a model where one of the two loci is under additive selection. We derive recursion equations for terms in the system and describe the moment hierarchy and a closure approximation, though we leave its development to future work. In the following we focus on neutral evolution.

Motivation: Heterozygosity across populations.

To motivate our derivation of the multi-population Hill-Robertson system and provide intuition, we begin with a model for heterozygosity across populations with migration. With two populations we consider the cross-population heterozygosity, , where p_i and q_i are allele frequencies at the left and right loci, respectively, in population i. This is the probability that two lineages, one drawn from each population, differ by state. At the time of split between populations 1 and 2, . Because coalescence between lineages in different populations is unlikely, is not directly affected by drift. In the absence of migration and under the infinite-sites assumption used here, this statistic increases linearly with the mutation rate over time (Fig A3 in S1 Appendix).

With migration, the evolution of also depends on and . We define the migration rate m₁₂ to be the probability that a lineage in population 2 has its parent in population 1. Assuming m_ij ≪ 1, the probability that both lineages in come from population 1 is m₁₂ (to leading order), in which case is equal to , and the probability that both come from population 2 is m₂₁. Then to leading order in m_ij, we have Similar intuition leads to recursions for and under migration, and this system easily extends to more than two populations.

The Hill-Robertson system with migration.

We take the same approach to determine transition probabilities in the multi-population Hill-Robertson system. Suppose that at some time, a population splits into two populations. At the time of the split, expected two-locus statistics (D², Dz, π₂) in each population are each equal to those in the parental population at the time of split (Appendix S1.2.1). Additionally, the covariance of D between the two populations, , is initially equal to in the parental population. In the absence of migration, Hill-Robertson statistics in each population evolve according to Eq 3, and (4)

With migration, additional moments are needed to obtain a closed system. These additional terms take the same general form as the original terms in the Hill-Robertson system, but include cross-population statistics, analogous to H₁₂ in the heterozygosity model with migration. Again using y to denote bases of Hill-Robertson moments, this basis is (5) where P is the number of populations, and we slightly abuse notation so that D_i D_j stands in for all index permutations (, , and D₁ D₂ in the two-populations case). We derive transition probabilities under continuous migration in Appendix S1.2.2 leading to the closed recursion, (6) where , , , and are sparse matrices for drift, migration, recombination and mutation that depend on the number of populations, population sizes N(t), and migration rates m.

Admixture.

Patterns of LD are sensitive to migration and admixture events, and low order LD statistics are commonly used to infer the parameters of admixture events [10, 29]. A well-known result (e.g., example 2.7 in [30]) is that D in an admixed population can be nonzero even when D is zero in both parental populations if allele frequencies differ between the two parental populations. This is seen by enumerating all possible combinations of haplotype sampling when a fraction f of lineages were contributed by population 1, and 1 − f by population 2 (Appendix S1.2.3). More generally, immediately following the admixture event, the expectation in the admixed population is (7) where δ = (p₁ − p₂)(q₁ − q₂) [31].

To integrate the multi-population D² system after an admixture event, we require and other second order terms in the basis (5) involving the admixed population. Using the same enumeration approach as for Eq 7, the expectation immediately following the admixture event is (8) Each other required term can be found in a similar manner (Appendix S1.2.3). In this way, the set of moments may be expanded to include the admixed population and integrated forward in time using Eq 6.

Validation.

We validated our numerical implementation and estimation of statistics from simulated genomes using msprime [32]. Expectations for low-order statistics match closely with coalescent simulations. For example, Fig A4 in S1 Appendix shows the agreement for a four population model with non-constant demography, continuous migration, and an admixture event, for which we computed expectations using moments.LD that matched estimates from msprime. While approximating expectations from msprime required the time-consuming running and parsing of many simulations, expectations from moments.LD were computed in seconds on a personal computer.

Genotype data.

Computing D using the standard definition requires phased haplotype data (Appendix S1.5). However, most currently available whole genome sequence data is unphased, so that we must rely on two-locus statistics based on observed genotype counts instead of haplotype counts. One could estimate haplotype statistics using the Weir [33] estimator (10) where n_A is the count of A at the left locus, n_B the count of B at the right locus, n_d the number of diploid individuals in the sample, and {n_AABB, n_AABb, …} the counts of each observed genotype. However, the Weir estimator for D is biased. Fortunately, we can simply treat the Weir estimator as a statistic and obtain an unbiased prediction for its expectation (Appendix S1.7.3). Even though can be estimated from 2n phased haplotypes, more samples are required to accurately estimate LD for a given pair of SNPs. However, as we are interested in genome-wide averages of and other LD statistics, even when individual estimates are noisy, by averaging over a very large number of pairs of SNPs we can accurately estimate LD from relatively few diploid genomes.

1000 Genome Project data.

We computed statistics from intergenic data in the Phase 3 1000 Genomes Project data [34]. The non-coding regions of the 1000 Genomes data is low coverage, which can lead to significant underestimation of low frequency variant counts, which distorts the frequency spectrum and can lead to biases in AFS-based demographic inference [35]. However, low-order statistics in the Hill-Robertson system are robust to low coverage data in a large enough sample size (Fig A6 in S1 Appendix), so that low coverage data are well suited for inference from LD statistics (see also [12]).

To avoid possible confounding due to variable mutation rate across the genome, we calculated and compared statistics normalized by π₂, the joint heterozygosity: , as in [12]. All figures showing -type statistics are normalized using π₂(YRI), the joint heterozygosity in the Yoruba from Ibidan, Nigeria (YRI). This normalization removes all dependence of the statistics on the overall mutation rate, so that estimates of split times and population sizes are calibrated by the recombination rate per generation instead of the mutation rate [23]. This is convenient given that genome-wide estimates of the recombination rate tend to be more consistent across experimental approaches than estimates of the mutation rate.

We considered all pairs of intergenic SNPs with 10⁻⁵ ≤ r ≤ 2 × 10⁻³ using the African-American recombination map estimated by Hinch et al. [36] using ancestry switch-points. The lower bound was chosen to further reduce the potential effect of short-range correlations of mutation rates, clustered mutations, experimental error, and low resolution of the recombination map at very short distances.

Likelihood-based inference on LD-curves.

To compare observed LD statistics in the data to model predictions, and thus to evaluate the fit of the model to data, we used a likelihood approach. We binned pairs of SNPs based on the recombination distance separating them (Appendix S1.7.2). Bins were defined by bin edges {r₀, r₁, …, r_n}, roughly logarithmically spaced. The model is defined by the set of demographic parameters Θ. We included the ancestral N_ref as a parameter to be fit, which we also use to scale recombination bins as ρ_i = 4N_refr_i.

For a given recombination bin (ρ_i, ρ_i+1], we computed statistics and normalized by π₂ in one population (we used π₂(YRI)), and denote this set of normalized statistics . We computed expectations for normalized statistics from the model, M_i, and then estimated the likelihood as taking the probability of observing data to be normally distributed with mean M and covariance matrix Σ (the normal distribution assumption is validated in Fig A5 in S1 Appendix).

We estimated Σ directly from the data by constructing bootstrap replicates from sampled subregions of the genome with replacement. This has the advantage of accounting for the covariance of statistics in our basis, as well as non-independence between distinct neighboring or overlapping pairs of SNPs. To compute the composite likelihood across ρ bins, we simply took the product of likelihoods over values of recombination bins indexed by i, so that To compute confidence intervals on parameters, we used the approach proposed by Coffman et al. [37], which adjusts uncertainty estimates to account for non-independence between recombination bins and neighboring pairs of SNPs.

Relation to other statistics.

There are many approaches for computing expected statistics for diversity under a wide range of scenarios. Single-site statistics, which include expected heterozygosity and the AFS, may be computed efficiently using forward- or reverse-time approaches. Beyond the classical recursions for and [12, 14], two-locus statistics are difficult to compute for non-equilibrium, multi-population demographic models. Sved [53] proposed an IBD based recursion to compute across subdivided populations, but its accuracy and interpretation remain debated [12].

The moments-based approach presented here generalizes the recursion for the single-site AFS presented in [3]. The moments system includes all heterozygosity statistics, so we recover expected F-statistics under arbitrary demography, which are commonly used to test for admixture [54–56]. Long-range patterns of elevated LD in putatively admixed populations are used to infer the timing of admixture events and relative contributions of parental populations [10, 29]. These approaches rely on the recursion for after admixture events that is used here (Eqs 2 and 7). Thus the generalized Hill-Robertson system is sensitive to ancient admixture, but also captures statistics used to identify recent admixture history, with fewer assumptions about early history.

Plagnol and Wall [57, 58] introduced a statistic, S*, specifically designed to scan for introgressed haplotypes without having sequence data from the diverged population. S* uses an ad-hoc score to identify SNPs that likely arose on haplotypes contributed from a deeply diverged population, and is estimated through simulation. These SNPs will tend to be rare and in high LD, and therefore also contribute to Dz (Fig 2D–2F). Thus even a small amount of archaic admixture will significantly elevate compared to that in an unadmixed population, and Dz itself could be used as an ad-hoc statistic similar to S*. Given its conceptual relationship to S*, it may not be so surprising that this previously overlooked statistic is particularly well suited for model-based inference of archaic admixture.

Caveats.

Like many inference approaches in population genetics, we approximate human history using discrete, randomly mating populations with size and migration histories described by relatively few parameters. History is much more complex than this. Thus statistical uncertainties estimated using bootstrap analysis masks much larger, systematic errors due to model misspecification. In particular, some choices we made in modeling archaic admixture are certainly oversimplified, such as the assumption of symmetric and constant migration rates during the period of contact between archaic and modern humans.

Variability in fine-scale recombination rates between populations and over time contributes another source of systematic error. While large-scale recombination rates are generally better understood than the mutation rate in humans [for which current estimates vary over a factor of two [59]], recombination rates can vary at short distances. Spence and Song [60] showed that recombination maps are highly concordant across populations represented in the Thousand Genomes Project [34], although this correlation surely decreases at shorter distances. We filtered out pairs of mutations at very close distances (less than roughly 1kb) to reduce potential biases due to very fine scale variation. We therefore do not expect variation in recombination rate among human populations to explain the large differences in Dz compared to the Gutenkunst et al. model. However, the effect of population-specific recombination maps may play a role when considering finer-scale patterns and data from deeply diverged populations such as the Neanderthal.

Finally, our model and inferences assumed that mutations are evolving neutrally. We chose to analyze SNPs in intergenic regions and excluded genic and intronic regions in an effort to reduce biases due to selection acting on mutations included in the analysis or nearby selected regions, although some intergenic regions are expected to be affected by selection or biased gene conversion. While outside the scope of this study, a more detailed characterization of the effects of linked selection on Hill-Robertson statistics is warranted.