On the cross-population generalizability of gene expression prediction models

Authors: Kevin L. Keys ^aff001; Angel C. Y. Mak ^aff001; Marquitta J. White ^aff001; Walter L. Eckalbar ^aff001; Andrew W. Dahl ^aff001; Joel Mefford ^aff001; Anna V. Mikhaylova ^aff003; María G. Contreras ^aff001; Jennifer R. Elhawary ^aff001; Celeste Eng ^aff001; Donglei Hu ^aff001; Scott Huntsman ^aff001; Sam S. Oh ^aff001; Sandra Salazar ^aff001; Michael A. Lenoir ^aff005; Jimmie C. Ye ^aff006; Timothy A. Thornton ^aff003; Noah Zaitlen ^aff008; Esteban G. Burchard ^aff001; Christopher R. Gignoux ^aff009
Authors place of work: Department of Medicine, University of California, San Francisco, California, United States of America ^aff001; Berkeley Institute for Data Science, University of California, Berkeley, California, United States of America ^aff002; Department of Biostatistics, University of Washington, Seattle, Washington, United States of America ^aff003; San Francisco State University, San Francisco, California, United States of America ^aff004; Bay Area Pediatrics, Oakland, California, United States of America ^aff005; Department of Epidemiology and Biostatistics, University of California, San Francisco, California, United States of America ^aff006; Department of Bioengineering and Therapeutic Biosciences, University of California, San Francisco, California, United States of America ^aff007; Department of Neurology, University of California, Los Angeles, California, United States of America ^aff008; Colorado Center for Personalized Medicine, University of Colorado Anschutz Medical Campus, Aurora, Colorado, United States of America ^aff009; Department of Biostatistics and Informatics, School of Public Health, University of Colorado Anschutz Medical Campus, Aurora, Colorado, United States of America ^aff010
Published in the journal: On the cross-population generalizability of gene expression prediction models. PLoS Genet 16(8): e32767. doi:10.1371/journal.pgen.1008927
Category: Research Article
doi: https://doi.org/10.1371/journal.pgen.1008927

Summary

The genetic control of gene expression is a core component of human physiology. For the past several years, transcriptome-wide association studies have leveraged large datasets of linked genotype and RNA sequencing information to create a powerful gene-based test of association that has been used in dozens of studies. While numerous discoveries have been made, the populations in the training data are overwhelmingly of European descent, and little is known about the generalizability of these models to other populations. Here, we test for cross-population generalizability of gene expression prediction models using a dataset of African American individuals with RNA-Seq data in whole blood. We find that the default models trained in large datasets such as GTEx and DGN fare poorly in African Americans, with a notable reduction in prediction accuracy when compared to European Americans. We replicate these limitations in cross-population generalizability using the five populations in the GEUVADIS dataset. Via realistic simulations of both populations and gene expression, we show that accurate cross-population generalizability of transcriptome prediction only arises when eQTL architecture is substantially shared across populations. In contrast, models with non-identical eQTLs showed patterns similar to real-world data. Therefore, generating RNA-Seq data in diverse populations is a critical step towards multi-ethnic utility of gene expression prediction.

Keywords:

Gene expression – Phenotypes – Europe – Population genetics – Gene prediction – African American people – Forecasting – Serial analysis of gene expression

Introduction

In the last decade, large-scale genome-wide genotyping projects have enabled a revolution in our understanding of complex traits [1–4]. This explosion of genome sequencing data has spurred the development of new methods that integrate large genotype sets with additional molecular measurements such as gene expression. A recently popular integrative approach to genetic association analyses, known as a transcriptome-wide association study (TWAS) [5,6], leverages reference datasets such as the Genotype-Tissue Expression (GTEx) repository [7] or the Depression and Genes Network (DGN) [8] to link associated genetic variants with a molecular trait like gene expression. The general TWAS framework requires previously estimated cis-eQTLs for all genes in a dataset with both genotype and gene expression measurements. The resulting eQTL effect sizes build a predictive model that can impute gene expression in an independently genotyped population. A TWAS is similar in spirit to the widely-known genome-wide association study (GWAS) but suffers less of a multiple testing burden and can potentially detect more associations as a result [5,6].

Unlike a normal GWAS, where phenotypes are regressed onto genotypes, in TWAS the phenotype is regressed onto the imputed gene expression values, thus constituting a new gene-based association test. TWAS can also link phenotypes to variation in gene expression and provide researchers with additional biological and functional insights over those afforded by GWAS alone. While these models are imperfect predictors, predicted gene expression allows researchers to test phenotype associations to expression levels in existing GWAS datasets without measuring gene expression directly. In particular, these methods enable analysis of predicted gene expression in very large cohorts (~10⁴–10⁶ individuals) rather than typical gene expression studies that measure expression directly (~10²–10³ individuals). Several methods have been recently developed to perform TWAS in existing genotyped datasets. PrediXcan [6] uses eQTLs precomputed from paired genotype-expression data, such as those in GTEx, in conjunction with a new genotype set to predict gene expression. These gene expression prediction models are freely available online (PredictDB), creating resources for external researchers. Related TWAS approaches, such as FUSION[5], MetaXcan [9], or SMR [10], leverage eQTL information with GWAS summary statistics instead, thus circumventing the need for raw individual-level genotype data.

As evidenced by application to numerous disease domains, the TWAS framework is capable of uncovering new genic associations [11–17]. However, the power of TWAS is inherently limited by the data used for eQTL discovery. For example, since gene expression varies by tissue type, researchers must ensure that the prediction weights are estimated using RNA from a tissue related to their phenotype, whether that be the direct tissue of interest or one with sufficiently correlated gene expression [18]. Furthermore, the ability of predictive models to impute gene expression from genotypes is limited by the heritability in the cis region around the gene [6]. Consequently, genes with little or no measurable genetically regulated effect on their expression in the discovery data are poor candidates for TWAS.

A subtler but more troubling issue arises from the lack of genetic diversity present in the datasets used for predictive model training: most paired genotype-expression datasets consist almost entirely of data from European-descent individuals [8,18]. The European overrepresentation in genetic studies is well documented [19–21] and has severe negative consequences for equity as well as for gene discovery [22], fine mapping [23–25], and applications in personalized medicine [26–34]. Genetic architecture, linkage disequilibrium, and genotype frequencies can vary across populations, which presents a potential problem for the application of predictive models with genotype predictors across multiple populations.

The training data for most models in the models derived from PrediXcan weights in PredictDB (predictdb.org) are highly biased toward European ancestry: GTEx version v6p subjects are over 85% European, while the GTEx v7 and DGN subjects are entirely of European descent. The lack of suitable genotype-expression datasets in non-European individuals leads to scenarios in which PredictDB models trained in Europeans are used to predict into non-European or admixed populations. As shown previously in the context of polygenic risk scores [35], multi-SNP prediction models trained in one population can suffer from unpredictable bias and poor prediction accuracy that impair their cross-population generalizability. Recent analyses of genotype-expression data from the Multi-Ethnic Study of Atherosclerosis (MESA) [36–38], which includes non-European individuals, explore cross-population transcriptome prediction and conclude that predictive accuracy is highest when training and testing populations match in ancestry. These results are consistent with our experience analyzing admixed populations, but offer little insight into the mechanisms underlying the cross-population generalizability of transcriptome prediction models, particularly when eQTL architecture is known.

Here we investigate the cross-population generalizability of gene expression models using paired genotype and gene expression data and using simulations derived from real genotypic data and realistic models of gene expression. We analyze prediction quality from currently available PrediXcan prediction weights using a pilot subset of paired genotype and whole blood transcriptome data from the Study of African Americans, Asthma, Genes, and Environment (SAGE) [39–42]. SAGE is a pediatric cohort study of childhood-onset asthma and pulmonary phenotypes in African American subjects of 8 to 21 years of age. To tease apart cross-population prediction quality, we turn to GEUVADIS and the 1000 Genomes Project datasets, which includes multiple populations each with more samples than our SAGE cohort [4,43,44]. The GEUVADIS dataset has been used extensively to validate PrediXcan models [6,38]. However, recent analyses suggest that GTEx and DGN PrediXcan models behave differently on the constituent populations in GEUVADIS [45,46]. GEUVADIS provides us an opportunity to investigate predictive models with an experimentally homogeneous dataset: the GEUVADIS RNA-Seq data were produced in the same environment under the same protocol, from lymphoblastoid cell lines (LCLs) that, despite some variation in when cells were collected [47], are derived from similar sampling efforts and treatments, thereby providing a high degree of technical harmonization. We train, test, and validate predictive models wholly within GEUVADIS with a nested cross-validation scheme. Finally, to understand the consequences of eQTL architecture on TWAS, we use existing 1000 Genomes data to simulate large samples of two ancestral populations and an admixed population and then apply the same “train-test-validate” scheme with various simulated eQTL models to study cross-population prediction efficacy when a gold standard is known.

Results

Concordance of measured gene expression and PrediXcan predictions is lower than expected

We compared transcriptome prediction accuracy in SAGE whole blood RNA using three PredictDB prediction weight sets for whole blood RNA: GTEx v6p, GTEx v7, and DGN. We also evaluated expression prediction with four of the MESA monocyte weight sets: MESA_ALL (populations combined), MESA_AFA (African Americans), MESA_AFHI (combined African Americans and Hispanic Americans), and MESA_CAU (Caucasians). For each gene where both measured RNA-Seq gene expression and predictions are available in SAGE, we compute both the coefficient of determination (R²) and Spearman correlation to analyze the direction of prediction. As we are primarily interested in describing the relationship between predicted outcome and real outcome, we prefer Spearman’s ρ to describe correlations, while for determining prediction accuracy, we use the standard regression R², corresponding to the squared Pearson correlation, to facilitate comparisons to prior work. We then benchmark these against the out-of-sample R² and correlations from GTEx v7 and MESA as found in PredictDB. Prediction results in SAGE were available for 11,545 genes with a predictive model from at least one weight set. Not all sets derived models at the same genes: since the estimation of these prediction models requires both high quality expression data and inferred eQTLs, each weight set from PredictDB may have a different number of gene models. Therefore, intersecting seven different weight sets reduces the overall number of models available for comparison. After applying the recommended filters, the prediction results across all seven weight sets overlapped at 273 genes, of which 39 genes had predictions with positive correlation to measurements. These subsets contained genes that were expressed somewhat higher than average (S1 Fig). This small number of genes in common is largely driven by MESA_AFA, the repository with the smallest number of predictive models. However, MESA_AFA contains the models that should best reflect the genetic ancestry of African Americans in SAGE (S1 Table). We note that MESA_AFA also has the smallest training sample size among our weight sets (N = 233) [38], so the small number of predicted genes from MESA_AFA probably results from the small training sample size and not from any feature of the underlying MESA_AFA training data.

Here, we highlight the union of genes across model sets for investigation. The concordance between predicted and measured gene expression over the union of 11,545 from all seven weight sets, with corresponding training metrics from PredictDB as benchmarks, shows worse performance than expected for R² (Fig 1) and correlations (Fig 2). The highest mean R² of 0.0298 was observed in MESA_AFA, while the lowest was observed in MESA_ALL (R² = 0.0250), suggesting little appreciable difference in prediction quality between prediction weight sets. R² for SAGE cluster heavily around 0 (S2 Fig), while R² for the prediction weight repositories show a wider distribution of R² (S3 Fig). We note the intersection of all prediction models is limited, but reflects a similar pattern: results for the 273 common genes (S4–S6 Figs) and the 39 genes with positive correlations (S7 and S8 Figs) showed little difference from the R² shown in Fig 1. Because SAGE is an independent validation set for the training populations, we would expect to observe some deterioration in prediction R² due to out-of-sample estimation. However, Fig 1 shows a marked difference in model performance.

A comparison of R<sup>2</sup> between prediction and measurement in SAGE, with PredictDB test metrics as benchmarks, for 11,545 genes total. — **Fig. 1. A comparison of R² between prediction and measurement in SAGE, with PredictDB test metrics as benchmarks, for 11,545 genes total.**
The prediction weights used here are, from left to right: GTEx v6p, GTEx v7, DGN, MESA African Americans, MESA African Americans and Hispanics, MESA Caucasians, and all MESA subjects. Test R² from model training in GTEx 7 and MESA (“test_R2_avg” in PredictDB) appear on the right and provide a performance baseline. The number of genes per weight set varies; see *S1 Table*.

**Fig. 2. Spearman correlations of measured gene expression versus predicted expression from PrediXcan.**
The order of the weight sets matches *Fig 1*. Test correlations for GTEx v7 and MESA correspond to “rho_avg” from PredictDB.

More noteworthy is the substantial proportion of predictions in SAGE with negative correlations to the real data. All seven weight sets produced gene expression predictions with negative correlations, but average performance across genes varied. The least negative mean correlation across prediction weight sets was observed in GTEx v6p (-0.0044), while the most negative mean correlation (-0.0204) was observed with MESA_AFA (MESA African Americans, S1 Table). The observation that correlations to SAGE measurements are sometimes negative on average suggests that some large R² values seen in Fig 1 may result from gene models with incorrect direction of prediction, thereby limiting interpretability of results. While there are some fluctuations in prediction accuracy, the fact that correlations vary from -0.0204 to -0.0044 indicates that no prediction weight set produces practically meaningfully better correlations to data than the others. In contrast, the published models for these genes show positive correlations to their training data, ranging from 0.308 in GTEx_v7 to 0.379 in MESA_AFA, indicating no obvious incapacity for accurate prediction, even with out-of-sample data. However, available predictions into SAGE from otherwise valid prediction models are uniformly limited in power to capture true genotype-expression relationships.

To analyze genes with high prediction R² in the original experiment, we focus on genes in GTEx v7 with cross-validated R² > 0.2 in the reference population. Our choice of R² is informed by observed R² between predictions and measurements in DGN (see Fig 3 of [6]) and focuses our analysis on genes predicted better than average. Fig 3 compares PredictDB testing R² against the empirical R² from regressing predictions onto observations in SAGE. In this case, even the better-imputed gene models derived from PredictDB have limited ability to capture gene expression accurately in SAGE (mean R² 0.031, IQR [0.0027, 0.037]). We see a similar trend with MESA models (S9–S12 Figs), in which R² in SAGE is consistently much lower (mean R² 0.026–0.030) than test R² from each prediction weight set (test R² 0.373–0.392).

A comparison of R<sup>2</sup> from SAGE and GTEx v7 training diagnostics. — **Fig. 3. A comparison of R² from SAGE and GTEx v7 training diagnostics.**
The SAGE R² are computed from regressing PrediXcan predictions onto gene expression measurements. The GTEx v7 R² are taken from PredictDB (“test_R2_avg”). The red dotted line marks where R² between the two groups match, while the blue line denotes the best linear fit.

Since SAGE data were ascertained on the basis of rs28450894 and by extension gene NFKB1 [39], we checked if results were biased by ascertainment. Among the 273 genes in common to all weight sets, only one gene model, SLC39A8, lay within 1 megabase in either direction of rs28450894 on chromosome 4. Only two of the SNP predictors for SLC39A8 showed more than moderate linkage disequilibrium (R² > 0.2) with rs28450894: SNP rs72696152 (MESA_ALL, R² = 0.675) and rs4648011 (DGN, R² = 0.262) (S3 Table). However, the resulting prediction quality were close to 0 like the remaining 272 genes, as the linear model R² for SLC39A8 ranged from 0.0007 (GTEx v7) to 0.0102 (GTEx v6p), indicating no obvious bias away from 0 (S4 Table).

Cross-population prediction quality declines with increasing genetic distance

Real-world comparisons of RNA-Seq datasets can be subject to numerous sources of heterogeneity besides differential ancestry. Possible confounders include technical differences in sequencing protocols, differences in the age of participants [48] or cell lines [47], and the postmortem interval to tissue collection (for GTEx) [49–51]. The small sample size of our SAGE cohort (n = 39) limits our ability to account for these possible confounders. To investigate cross-population generalizability in an experimentally homogeneous context, we turn to GEUVADIS [43]. The GEUVADIS data include two continental population groups from the 1000 Genomes Project: the Europeans (EUR373), composed of 373 unrelated individuals from four subpopulations (Utahns (CEU), Finns (FIN), British (GBR), Toscani (TSI)), and the Africans (AFR) composed of 89 unrelated Yoruba (YRI) individuals. In light of the known bottleneck in Finnish population history [52], we analyze EUR373 both as one population and as two independent subgroups: the 95 Finnish individuals (FIN) and the 278 non-Finnish Europeans (EUR278). We used expression data, generated and harmonized together by the GEUVADIS Consortium, with matched whole-genome genotype data in the resulting four populations (EUR373, EUR278, FIN, and AFR) to train predictive models for gene expression in a nested cross-validation scheme [6] and perform cross-population tests of prediction accuracy.

Table 1 shows R² from three training sets (EUR373, EUR278 and AFR) into the four testing populations (EUR373, EUR278, FIN, and AFR) for genes with positive correlation between prediction and measurement. While the number of genes with applicable models including genetic data varies in each train-test scenario (see S5 Table), we note that not all predictive models are trained on equal sample sizes, so the resulting R² only provide a general idea of how well one population imputes into another; see S13 Fig for a distributional summary. Analyses within a population use out-of-sample prediction R² to avoid overfitting across train-test scenarios. Predicting from a population into itself yields R² ranging from 0.079–0.098 (Table 1) consistent with the smaller sample sizes in GEUVADIS versus GTEx and DGN. In contrast, predicting across populations yields more variable predictions, with R² ranging from 0.029–0.087. At the lower range of R² (0.029–0.039) are predictions from AFR into European testing groups (EUR373, EUR278, and FIN). Alternatively, when predicting from European training groups into AFR, the R² are noticeably higher (0.051–0.054). Prediction from EUR278 into FIN (R² = 0.087) is better than prediction from EUR278 into AFR (R² = 0.051), suggesting that prediction R² may deteriorate with increased genetic distance. A comparison of the 564 genes in common across all train-test scenarios (Table 2) yields a subset of genes with potentially more consistent gene expression levels (see S14 Fig for distributional summaries). In this case involving better-predicted genes, we see that prediction quality between the European groups improves noticeably (p-value ~ 0, Dunn test). Among European training sets, the lowest R² is 0.183 for EUR278 predicting into EUR278. R² increases to 0.201 (EUR373 to EUR373) and attains its maximum at 0.216 (EUR278 to FIN), possibly a consequence of diminished haplotypic diversity from Finnish population bottlenecking as mentioned previously. In contrast, R² between Europeans and Africans ranges from 0.095 (AFR to EUR373) to 0.147 (EUR373 to AFR), a significant improvement (p-value < 7.07 x 10⁻²², Dunn test) that nonetheless highlights a continental gap in prediction performance. AFR predicts better into FIN (R² = 0.111) than the other European populations (R² = 0.095–0.096), similar to what we observe with predictions from EUR373 into FIN. But AFR predicts better into itself (R² = 0.130) than to other populations; similarly, European predictions into AFR are noticeably lower (R² = 0.141–0.147) than into other European populations (R² = 0.183–0.216). In general, populations seem to predict better into themselves, and less well into other populations.

Prediction R<sup>2</sup> between populations in GEUVADIS for genes with positive correlation between predictions and measurements. — **Tab. 1. Prediction R² between populations in GEUVADIS for genes with positive correlation between predictions and measurements.**

Prediction R<sup>2</sup> between populations in GEUVADIS for 564 gene models that show positive correlation between prediction and measurement in all 9 train-test scenarios that were analyzed. — **Tab. 2. Prediction R² between populations in GEUVADIS for 564 gene models that show positive correlation between prediction and measurement in all 9 train-test scenarios that were analyzed.**

Combining all European subpopulations obscures population structure and can complicate analysis of cross-population prediction performance. To that end, we divide the GEUVADIS data into its five constituent populations and randomly subsample each of them to the smallest population size (n = 89). We then estimate models from each subpopulation and predict into all five subpopulations. Table 3 shows average prediction R² from each population into itself and others (see S15 Fig for distributional summaries). The populations consistently predict well into themselves, with prediction R² ranging from 0.104–0.136. We observe that prediction quality using models trained in CEU shows a miniscule decline relative to other EUR subpopulations. This observation is potentially due to the older age of CEU LCLs [45,53,54], but did not appreciably change our results. In contrast, a more notable difference exists between the EUR subpopulations and YRI. The cross-population R² between CEU, TSI, GBR, and FIN ranges from 0.103 to 0.137, while cross-population R² from these populations into YRI ranges from 0.062 to 0.084. Prediction between YRI and the EUR populations taken together is consistently lower than within the EUR populations (S17 Fig) and statistically significant (p-value < 1.36 x 10⁻⁴, Dunn test; see S8 Table). The cross-population differences remain for the 142 genes with positive correlation in all train-test scenarios (Table 4, S16 Fig), where R² for prediction into YRI ranges from 0.166 to 0.244, while R² within EUR populations ranges from 0.239 to 0.331. These results clearly suggest problems for prediction models that predict gene expression across populations, in similar regimes to those tested with linear predictive models and datasets of size consistent with current references. In addition, since AFR is genetically more distant from the EUR subpopulations than they are to each other, we interpret these results to imply that structure in populations can potentially exacerbate cross-population prediction quality (S18 Fig).

**Tab. 3. Cross-population prediction performance across all five constituent GEUVADIS populations over genes with positive correlation between predictions and measurements.**

Tab. 4. Cross-population prediction performance across all five subsampled GEUVADIS populations over the 142 genes with positive correlation between prediction and measurement in all 25 train-test scenarios.

Admixture influences cross-population gene expression prediction quality under known eQTL architecture

The unresolved question is the extent to which these results hold with oracle knowledge of eQTL architecture, something impossible to investigate in real data when the causal links between eQTLs and gene expression can only be estimated. To investigate genomic architectures giving rise to gene expression, and in particular to investigate behavior in admixed populations, we forward-simulated haplotypes from HapMap3 [55] CEU and YRI using HAPGEN2 [56] and then sample haplotypes in proportions consistent with realistic admixture proportions (80% YRI, 20% CEU) [57] to construct a simulated African-American (AA) admixed population. We simulated n = 1000 samples for each population, a much larger sample than what is available in GEUVADIS and comparable to the training sample size of DGN or MESA_ALL PrediXcan models. We simulated eQTL architectures under an additive model of size k causal alleles (k = 1, 10, 20, and 40) in the ancestral populations (CEU and YRI) and an expression phenotype with cis-heritability h² = 0.15 (recapitulating the average h² in DGN whole blood RNA-Seq data [6]) using the genomic background of genic regions on chromosome 22, thus testing various model sizes and LD patterns. To tease apart the effect of shared eQTL architecture, we allow the two ancestral populations CEU and YRI to share eQTLs with fixed effects in various proportions (0%, 10%, 20%, …, 100%) to test a range of eQTL architectures. The admixed population AA always inherited all eQTLs from the two ancestral populations, which yielded different numbers of eQTLs per gene depending on how many eQTLs were shared by CEU and YRI. For example, for eQTL model size k = 10, when CEU and YRI shared all 10 eQTLs, then all three populations had the exact same 10 eQTLs. When CEU and YRI shared half of their eQTLs with each other, then each one had 5 population-specific eQTLs, and AA inherited 15 total eQTLs (5 unique to CEU, 5 unique to YRI, and 5 shared). If CEU and YRI shared no eQTLs, then all eQTLs were population-specific, and AA inherited 20 eQTLs (10 from CEU and 10 from YRI; see S19 Fig for an illustration). With these simulations providing known architectures for comparison, we then apply the train-test-validate scheme as before.

Fig 4 shows the cross-population Spearman correlations between predicted and simulated phenotypes in our simulated AA, CEU, and YRI, partitioned by proportion of shared eQTLs, for k = 10 causal eQTLs in the ancestral populations (CEU and YRI). Scenarios with k = 20 and k = 40 causal eQTLs show similar trends (S20 Fig and S21 Fig). Prediction within a population produced similar correlations in all cases, ranging from 0.310 to 0.338 (S6 Table). The case of models with 100% shared eQTL architecture–where eQTL positions and effects are exactly the same between the ancestral populations–yields predictions with no loss in cross-population generalizability, with correlations ranging from 0.299 to 0.336 even when predicting across populations (S7 Table). This case suggests that eQTLs that are causal in all populations can impute gene expression reliably regardless of the population in which they were ascertained, provided that the eQTLs can be correctly mapped and genotyped in all populations, that the eQTL effects are identical across populations, and that a linear model of eQTLs is assumed. For cases where eQTL architecture is not fully shared across populations, we see that prediction from each population into the other improves as the proportion of shared eQTLs increases (Fig 4). The cross-population correlation between predicted gene expression versus measurement is highest from YRI to AA (0.238 to 0.338), intermediate from CEU to AA (0.218 to 0.310), and lowest between CEU and YRI (0.0020 to 0.326). Prediction quality from AA to CEU and YRI interpolates that of YRI to AA and CEU to AA, with correlations ranging from 0.223 to 0.338. Prediction quality from AA to CEU or YRI shows a slight upward trend as more eQTLs are shared, an artifact of eQTL inheritance in our simulations; as described previously, AA eQTL models are largest (20 eQTLs) when CEU and YRI share no eQTLs and smallest (10 eQTLs) when CEU and YRI share all eQTLs. Consequently, when predicting between two populations, the choice of which population is used to train predictive models can produce differences in prediction quality. Prediction quality between AA to CEU and AA to YRI is not significantly different (p-value ~ 1, Dunn test). All other train/test scenarios are significantly different from each other (S9 Table). The results for k = 10, 20, and 40 eQTLs show a consistent trend of prediction quality driven primarily by differences in eQTL architecture, with additional minor influence from ancestral similarity between populations (k = 10, Fig 4, similar plots in S20 Fig and S21 Fig). Although less realistic for most genes [5,6,18], we also analyzed models with a single causal eQTL. Trends for single-eQTL models are more difficult to analyze due the limitations of binary inference as to whether the causal SNP is identified or not. Nevertheless, when the causal eQTL is identified and shared across populations, prediction quality is high in all cases. If the causal eQTL differs across populations, then cross-population prediction between AA and YRI or CEU is noticeably better than prediction between CEU and YRI (S22 Fig), in line with results for other values of k that suggest that eQTL sharing is the primary driver of gene expression prediction quality.

**Fig. 4. Correlations between predictions and simulated gene expression measurements from simulated populations across various proportions of shared eQTL architecture with 10 causal cis-eQTLs.**
Here YRI is simulated from the 1000 Genomes Yoruba, CEU is simulated from the Utahns, and AA is constructed from YRI and CEU. The black line represents the upper bound of correlation 0.387 dictated by our choice h² = 0.15 for the genetic heritability of expression. Each trend line represents an interpolation of correlation versus shared eQTL proportion. Gray areas denote 95% confidence regions of LOESS-smoothed mean correlations conditional on the proportion of shared eQTLs.

Power to detect associations declines with decreasing shared ancestry

Simulation of gene expression demonstrates that gene expression prediction quality is modulated by both shared eQTL architecture and shared genetic ancestry. These results suggest possible effects of cross-population generalizability on the power to detect associations between a phenotype and gene expression measures in a TWAS. For each of our three populations (AA, CEU, and YRI), we used the simulated gene expression measures to simulate a continuous phenotype whose variation depends on expression of a single causal gene. For simplicity, the phenotypes shared the same causal gene, the same effect size, and the same environmental noise model. We tested various effect sizes from 1 x 10⁻⁵ to 1 and drew the environmental noise from a zero-mean normal distribution with variance 0.01. The effect sizes produced a continuous spectrum of genetic heritability values h² spanning the full range of heritability for gene expression. We then regressed the phenotype onto predicted gene expression measures, resulting in nine association tests, one for each train-test scenario. For simplicity, we focused on the prediction scenario with k = 10 causal eQTLs per gene. To see how shared eQTL architecture affects power, we used predicted expression measures with 0%, 50%, and 100% shared eQTLs per gene.

Fig 5 shows power curves for the association tests for the nine prediction scenarios for all three tested eQTL architectures. Unsurprisingly, power improves as populations share more causal eQTLs and as more phenotypic heritability is driven by gene expression. For example, with 100% shared eQTLs and phenotypic heritability 0.205, cross-population power ranges between 0.69–0.86. In contrast, average power under a model of 0% shared eQTLs between ancestral populations (CEU to YRI, YRI to CEU), varies from a scant 0.02 to 0.14 as phenotype heritability increases from 0 to 1, indicating some ability to predict gene expression at genetically controlled genes even without shared eQTLs. AA shows better cross-population power, ranging from to 0.38 (AA to YRI, AA to CEU) to 0.82 (CEU to AA) and 0.88 (YRI to AA), an expected outcome since AA inherits all eQTLs from the ancestral populations. Power also improves with shorter genetic distance between populations. Fig 6, which is a cross-section of Fig 5, shows power for each train-test scenario across various shared eQTL architectures for β = 0.05, corresponding to a phenotype heritability of h² = 0.205, indicating moderate genetic control. TWAS in this case using gene expression imputed from matched populations has higher power across all eQTL architectures, from 0.88–1.00, compared to cross-population TWAS, where power varies substantially. For an architecture with no shared eQTLs, power between CEU and YRI is 0.02, while power is higher for CEU to AA (0.82) and YRI to AA (0.86). TWAS power for expression predicted from AA to CEU (0.39) or YRI (0.38) is much lower due to the aforementioned structure of eQTL inheritance; when CEU and YRI share 0 of 10 eQTLs, AA has 20 eQTLs, 10 from each ancestral population. As the proportion of shared eQTLs jumps from 0% to 50% and 100%, power increases across all cross-population scenarios, reaching up to 0.86 (YRI to AA, 100% shared eQTLs). When eQTLs are fully shared, power from YRI to AA (0.86) is higher than from CEU to AA (0.83), indicating an effect of genetic distance on prediction quality. Indeed, when controlling for eQTL architecture, increasing genetic similarity between reference and target populations yields more significant median association test t-statistics (S23 Fig).

**Fig. 5. Curves depicting power to detect association under various TWAS scenarios.**
The x-axis represents the proportion of phenotypic variance explained by gene expression. As in *Fig* 4, AA reflects simulated African-Americans constructed from YRI and CEU. The curves represent logistic interpolations of whether or not the causal gene was declared significant in an association test of a phenotype from the testing population with gene expression predicted from a training population into the testing population. Gray areas denote 95% confidence regions of mean power conditional on the effect size.

Power for phenotype-expression association tests with cross-population imputed gene expression for heritability h<sup>2</sup> = 0.205. — **Fig. 6. Power for phenotype-expression association tests with cross-population imputed gene expression for heritability h² = 0.205.**
The cross-population scenarios are ordered left to right from least admixture (CEU to YRI, 0% admixture proportion in our simulation) to most admixture (YRI to AA, 80% admixture proportion). Power increases on two axes: (1) as the proportion of shared eQTL architecture increases, and, to a lesser extent, (2) as genetic distance decreases between reference and target populations. Power is consistently high when training and testing populations match.

Admixture proportion interpolates power in two-way admixture

The results in Fig 6 show how genetic distance affects power in TWAS association tests for one particular admixture proportion, but offer limited insight about how power changes across the admixture spectrum. To understand how admixture proportion affects TWAS power in a general admixed population with two ancestral populations, we simulated multiple admixed populations from CEU and YRI with admixture proportions varying at 10% increments. When the admixed population has 0% YRI admixture, it is fully drawn from haplotypes from CEU, whereas a population with 100% YRI admixture is drawn exclusively from haplotypes from YRI. It is important to note that in neither case does the admixed population exactly match the reference CEU or YRI since the genotypes for the admixed population are formed from an independent shuffling of the CEU or YRI haplotypes. For each admixed population, we estimated prediction models of gene expression as done in our previous analyses. For computational efficiency, we investigated the scenario of 50% shared eQTLs across reference populations and the number of eQTLs per gene equal to 10. Populations still shared the same causal gene, effect size, and environmental noise model.

Fig 7 shows power across admixture proportions for all cross-population scenarios. The phenotypes were simulated at effect sizes β = 0.005, 0.01, and 0.025, and environmental variance σ² = 0.01, corresponding to heritability h² = 0.06, 0.20, and 0.58, respectively. To compare and contrast across each train and test scenario, we plot the overall trends of performance in Fig 7, and provide the exact mean power estimates and 95% confidence intervals for each scenario in S10–S12 Tables. To avoid confusion with previous references to AA, which had a fixed admixture proportion, here we denote the admixed population for all proportions as AD. As expected, statistical power increases with the genetic heritability of the phenotype for all prediction scenarios. However, the different admixture proportions yield directional changes in power when gene expression is predicted to or from AD. For example, when h² = 0.20 and gene expression is predicted from AD to CEU, power at 0% YRI admixture is 0.56 (95% CI: 0.462–0.658) and declines linearly with increasing YRI admixture; at 100% YRI, statistical power for AD to CEU is 0.46 (95% CI: 0.362–0.558). For AD to YRI, power at 0% YRI admixture starts at 0.42 (95% CI: 0.323–0.512) and increases linearly to 0.53 (95% CI: 0.431–0.628) at 100% YRI. We observe similar changes in power for CEU to AD (decreasing power as YRI proportion increases) and YRI to AD (increasing power as YRI proportion increases). The four directional trends also hold for h² = 0.06 and h² = 0.58, though power for cross-population scenarios involving AD is much lower in the former case and almost universally high in the latter case. In essence, the varying admixture proportions in this two-way admixed population yield a continuous linear trend of statistical power between the two ancestral populations: when AD is genetically closer to CEU, power for gene expression predicted in these populations is highest, and declines as AD becomes genetically closer to YRI. Similarly, when predicting from AD to YRI or vice versa, power is lowest when the two populations are genetically distinct, intermediate as the two populations become more genetically similar, and maximized when they are most alike.

Power for various cross-population train-test scenarios with varying YRI admixture for three phenotypic heritability levels h<sup>2</sup> = 0.06, 0.20, and 0.58, corresponding to effect sizes 0.005, 0.01, and 0.025, respectively. — Fig. 7. Power for various cross-population train-test scenarios with varying YRI admixture for three phenotypic heritability levels h² = 0.06, 0.20, and 0.58, corresponding to effect sizes 0.005, 0.01, and 0.025, respectively.
Power increases as heritability increases, but also as populations become more genetically similar. Raw power estimates and 95% confidence intervals are listed in *S10*–*S12* Tables.

Discussion

Our goal with this study was to understand the extent to which gene expression prediction models estimated in one population can accurately predict the genetic component of gene expression in a different population. Cross-population generalizability of gene expression prediction models is an important but understudied issue for TWAS analyses. Among TWAS resources, we focused on PrediXcan as a test case with openly distributed prediction models available for multiple populations [6,38]. Using 39 subjects from the SAGE study [39–42] we compared predicted expression values from PrediXcan models to measured gene expression on the same subjects and found that predictions matched poorly to measurements. Our investigation with the GEUVADIS dataset [43] offered us a more homogenous environment and larger sample size in which to train and test gene expression prediction models. Prediction quality in GEUVADIS using both continental and constituent subpopulations provided stronger evidence of cross-population generalizability issues with transcriptome prediction, but could not control for eQTL predictors that vary between populations. To that end, our simulation of an admixed population from 1000 Genomes CEU and YRI haplotypes [4,44] allowed us to finely control eQTL positions and effects as well as the causal genes in a TWAS. The simulation results show that both gene expression prediction accuracy and statistical power decrease as population eQTL models begin to diverge and genetic distance increases between populations for varying admixture proportions.

Our results highlight two points: firstly, since prediction within populations is better than prediction between populations, our results reaffirm prior investigations [38] that population matching matters for optimally predicting gene expression. This is consistent with our results of impaired transcriptome prediction performance in SAGE with currently available resources. Secondly, despite decreased prediction accuracy when predicting between different populations, the populations that are more closely genetically related demonstrate somewhat better cross-population prediction and power to detect associations in TWAS. Our simulations of prediction between ancestral populations and an admixed one under varying admixture proportions neatly summarize this relationship: the admixture proportion from each ancestral population interpolates the power available from each ancestral population, and power is maximized when the admixed population is most closely related to one or the other ancestral population. However, while the differences in power under varying admixture are statistically meaningful, they are smaller than differences attributable to different eQTL architectures or to different levels of genetic heritability of a phenotype.

Prediction results from GTEx, DGN, and MESA into SAGE suggest that current predictive models, even for genes with greater heritability, perform worse than expected despite matching tissue types. Our investigation into cross-population prediction accuracy with GEUVADIS data replicates this lack of cross-population generalizability as observed with current predictive models from PredictDB, demonstrating that heterogeneity in RNA-Seq protocols does not fully explain our observations. Our results parallel prior evidence [45] that PredictDB models themselves do not predict as well as expected into GEUVADIS despite controlling for tissue type, strongly suggesting that our observations about PrediXcan predictions in SAGE could hold true in other datasets. Since transcriptome prediction models use multivariate genotype predictors trained on a specific outcome, the impaired cross-population application can be viewed as an analogous observation to that seen previously in polygenic scores [35].

Our simulations control for many technical issues that are otherwise difficult to overcome with real data, such as oracular knowledge of positions and effect sizes of causal eQTLs. Nevertheless, in our simulations we see issues with cross-population prediction that we first observed when applying existing PrediXcan models to SAGE genotype data. Certainly, SAGE differs in important ways from GTEx, DGN, and MESA: SAGE is a pediatric asthma case-control cohort study in African-American children, so we cannot rule out technical heterogeneity introduced by differences in age, study design, and ethnicity. Furthermore, our SAGE sample includes RNA-Seq data for n = 39 subjects, a dataset leveraged previously to validate genetic associations, but is nevertheless somewhat small by contemporary standards [39]. However, technical heterogeneity between SAGE and existing PrediXcan models cannot solely explain the poor prediction performance. Our simulation results strongly suggest that problematic cross-population prediction performance between PrediXcan models and SAGE is deeper than differences in expression data.

Our investigations into the architecture of gene expression indicate that the power to detect associations is primarily determined by the degree of shared eQTLs across populations. In our simulations, this can be approximated as a (quasi-)linear interpolation of the prediction in the ancestral or reference populations into the admixed populations. However, the same is not true of overall levels of power in the admixed population: under 100% shared eQTL scenarios, cross-population generalizability is high, so the choice of training population matters less. In practical terms, this result bodes well for prediction of genes with eQTLs that do not vary by population. It is curious that in high-heritability genes, even models that share no eQTLs still retain power to detect scenarios: for genetically distant populations (CEU and YRI), power ranges from 0.10–0.14. Without shared eQTLs, this implies that local linkage disequilibrium between population-specific eQTLs, combined with high heritability, enables some degree of cross-population prediction. When cross-population statistical power is driven by LD and h² instead of expression signals, then subsequent interpretation of association hits, such as direction and strength of effect, becomes difficult to link to actual biological relationships between phenotype and gene expression.

It is important to note that our observations do not reflect shortcomings of either the initial PrediXcan or TWAS frameworks. Nor do our findings affect the positive discoveries made using these frameworks over the past several years. These methods fully rely on the data used as input for training, and the most commonly used datasets for model training are overwhelmingly of European descent. Here we note that the current models fail to capture the complexity of the cross-population genomic architecture of gene expression for populations of non-European descent. Failing to account for this could lead researchers to draw incorrect conclusions from their genetic data, particularly as these models would lead to false negatives.

To this end, our simulations strongly suggest that predicting gene expression in a target population is improved by using predictive models constructed in a genetically similar training population. Maximizing prediction quality crucially depends on both genetic architecture and eQTL architecture. If populations share the exact same eQTL architecture, then they are essentially interchangeable for the purposes of gene expression prediction so long as eQTLs are genotyped and accurately estimated, which remains a technological and statistical challenge. As the proportion of shared eQTL architecture decreases between two populations, both cross-population prediction quality and TWAS power decrease as well. In both SAGE and GEUVADIS, we observe cross-population patterns consistent with an imperfect overlap of eQTLs across populations. Ensuring representative eQTL architecture for all populations in genotype-expression repositories will require a solid understanding of true cross-population and population-specific eQTLs. However, expanding the amount of global genetic architecture represented in genotype-expression repositories, which can be accomplished by sampling more populations, provides the most desirable course for improving gene expression prediction models. Additionally, this presents an opportunity for future research in methods that could improve cross-population generalizability, particularly when one population is over-represented in reference data. Tools from transfer learning could facilitate porting TWAS eQTL models from reference populations to target populations using little or no RNA-Seq data.

In light of the surging interest in gene expression prediction and TWAS, we see a pressing need for freely distributed predictive models of gene expression estimated from coupled transcriptome-genome data sampled in a variety of populations and tissues. The recently published predictive models with multi-ethnic MESA data constitute a crucial first step in this direction for researchers working with admixed populations [38]. However, the clinical and biomedical research communities must push for more diverse genotype-expression resources to ensure that the fruits of genomic studies benefit all populations.

Online resources

PredictDB: http://predictdb.org/

GTEx: http://gtexportal.org/

DGN: http://dags.stanford.edu/dgn/

GEUVADIS: https://www.ebi.ac.uk/Tools/geuvadis-das/

Source code: https://github.com/asthmacollaboratory/sage-geuvadis-predixcan

Results and simulation data: https://doi.org/10.7272/Q6RN362Z

Methods

Ethics statement

This study uses data from the Study of African Americans, Asthma, Genes, and Environments (SAGE) cohort, approved for human subjects research under expedited review by UCSF IRB 10–02877 with reference #244919. All subjects gave written consent for genotyping, phenotyping, and data usage for general research use.

Genotype and RNA-Seq data

RNA-Seq (RNA sequencing) data generation and cleaning protocols for 39 SAGE subjects analyzed here were initially described in (Mak, White, Eckalbar, et al. 2018) [39]. Genotypes were generated on the Affymetrix Axiom array as described previously [58]. Genotypes were then imputed on the Michigan Imputation Server [59] with EAGLE v2.3 [60] and the 1000 Genomes panel phase 3 v5 [44] and then subjected to the following filters: missing samples < 5%, missing genotypes at any given SNP <5%, SNP minor allele frequency > 1%, p-value for deviation from Hardy-Weinberg Equilibrium >1 x 10⁻⁴, and genotype imputation R² > 0.3. The choice of the 1000 Genomes panel follows GTEx protocol, though GTEx used the smaller 1000 Genomes phase 1 panel [4]. Gene expression counts were processed through the GTEx v6p eQTL quality control pipeline and as described previously [18]. Per GTEx protocol, gene expression values were corrected for 3 genotype principal components, 15 PEER factors, and sex. Gene expression values were filtered to have >0.1 reads per kilobase per million reads (RPKM) in at least 10 individuals and at least 6 reads in at least 10 individuals. This filtering process kept 20,985 genes with Ensembl identifiers for analysis, of which 20,268 were autosomal genes. We then quantile normalized the remaining gene expression values across samples as our gene expression measurements.

GEUVADIS genotype VCF files and normalized gene expression data (filename GD462.GeneQuantRPKM.50FN.samplename.resk10.txt.gz) were downloaded directly from the EMBL-EBI GEUVADIS Data Browser. Genotypes were filtered similarly to SAGE subjects. No manipulation was performed on expression data. This process yielded 23,722 genes for analysis.

Running PrediXcan models

We ran PrediXcan on SAGE subjects using PredictDB prediction weights from three paired genotype-expression datasets from PredictDB: GTEx, DGN, and MESA [6,9,38,61]. For GTEx, we used both GTEx v6p and GTEx v7 weights. For MESA, we used all weight sets from the freeze dated 2018-05-30: African Americans (MESA_AFA), African Americans and Hispanics (MESA_AFHI), Caucasians (MESA_CAU), and all MESA samples (MESA_ALL). Overall, the analysis included 11,545 genes, of which only 273 had both normalized RNA-Seq measures and predictions from all weight sets. Of these, 126 had positive correlation between prediction and measurement. We assessed prediction quality by comparing PrediXcan predictions to normalized gene expression from SAGE using linear regression and correlation tests.

Estimation of prediction models

We trained prediction models in GEUVADIS on genotypes in a 500Kb window around each of 23,723 genes with measured and normalized gene expression. GEUVADIS subjects were partitioned into various groups: the Europeans (EUR373), the non-Finnish Europeans (EUR278), the Yoruba (AFR), and the constituent 1000 Genomes populations (CEU, GBR, TSI, FIN, and YRI). For each training set, we performed nested cross-validation. The external cross-validation for all populations used leave-one-out cross-validation (LOOCV). The internal cross-validation used 10-fold cross-validation for EUR373 and EUR278 and LOOCV for the five constituent GEUVADIS populations in order to fully utilize the smaller sample size (n = 89) compared to EUR278 (n = 278) and EUR373 (n = 373). Internal cross-validation used elastic net regression with mixing parameter 𝛼 = 0.5 as implemented in the glmnet package in R. The nonzero weights for each SNP from each LOOCV were compiled and averaged for each gene, yielding a single set of prediction weights for each gene. Predictions were computed by parsing genotype dosages from the target population corresponding to the nonzero SNP predictors, and then multiplying dosages against the prediction weights. The resulting predictions were compared to normalized gene expression measurements downloaded from the GEUVADIS data portal. We applied two additional filters to ensure that gene expression models were suitable for analyses. Firstly, we removed genes that did not have any eQTLs in their predictive models. Secondly, genes where fewer than half of the individuals had nonmissing predictions were removed from further analysis. This latter filter discarded those genes for which expression was not easy to predict across multiple samples. Coefficients of determination (R²) were computed with the lm function in R. Spearman correlations were computed with the cor.test function in R.

Simulation of gene expression

We downloaded a sample of 20,085 HapMap 3 SNPs [55] from each of CEU and YRI on chromosome 22 as provided by HAPGEN2 [56]. The data include 234 phased haplotypes for CEU and 230 phased haplotypes for YRI. We forward-simulated from these haplotypes to obtain two populations of n = 1000 individuals each. We then sampled haplotypes in proportions of 80% YRI and 20% CEU to obtain a mixture of CEU and YRI where the ancestry patterns roughly mimic those of African Americans. For computational simplicity, and in keeping with the high ancestry LD present in African Americans [62,63], for each gene we assumed local ancestry was constant for each haplotype. For each of the three simulated populations, we applied the same train-test-validate scheme used for cross-population analysis in GEUVADIS. Genetic data for model simulation were downloaded from Ensembl 89 and included the largest 100 genes from chromosome 22. We defined each gene as the start and end positions corresponding to the canonical transcript, plus 1 megabase in each direction. We removed two genes, PPP6R2 and MOV10L1, that spanned no polymorphic markers within 2 megabases of their start and end positions in the HapMap3 dataset, resulting in 98 gene models used for analysis. To simulate predictive eQTL models, we tested multiple parameter configurations for each gene: we varied the number of causal eQTLs in the ancestral populations (k = 1, 10, 20, and 40) and the proportion of shared eQTL positions (p = 0.0, 0.1, 0.2, …, 0.9, 1) between ancestral populations. The admixed population always inherited all eQTLs from the ancestral populations. Causal eQTLs were chosen at random among SNPs with at least 5% minor allele frequency. The same 5% minor allele frequency floor was applied to each population. Each model included a simulated gene expression phenotype with cis-heritability set to 0.15. For each parameter configuration, we ran 100 different random instantiations of the model simulations.

Simulation of TWAS

Using the simulated gene expression measures with k = 10 causal eQTLs per gene in ancestral populations, we simulated a continuous phenotype with a known genetic architecture that depended on 1 causal gene. We tested prediction scenarios with 0%, 50%, and 100% eQTLs shared across populations. For each eQTL architecture, the three populations AA, CEU, and YRI shared the same causal gene G, the same causal effect size β, and the same environmental noise ε. G was chosen randomly. Effect sizes were fixed, and we tested various effect magnitudes β = 1 x 10⁻⁵, 5 x 10⁻⁵, 1 x 10⁻⁴, …, 1 x 10⁻¹, 5 x 10⁻¹, 1, yielding a spectrum of phenotype heritability explained by gene expression. The environmental noise ε was drawn from an N(0,0.1²) distribution. Consequently, phenotypes therefore only varied with the expression measures from G. For a given population c, the phenotype y_c was then simulated as

For each combination of shared eQTL architecture, G, and β, this procedure yielded one y_c per individual in a population. We then performed a TWAS with y_c onto the predicted gene expression values, yielding three TWAS per y_c, one for each reference prediction population. We then queried the resulting association p-value at G and tabulated whether it was declared significant (yes) or not (no) against a Bonferroni-corrected threshold of 0.05 / 98, accounting for all 98 genes in the TWAS. We ran this procedure for 100 random instantiations of (G, ε) and computed association test power with a logistic interpolation of the yes/no results.

Analysis tools

Analyses used GNU parallel [64]. The R packages used for analysis include argparser, assertthat, data.table, doParallel, dunn.test, knitr, optparse, peer, the Bioconductor packages annotate, biomaRt, and preprocessCore, and the tidyverse bundle [65–76]. All plots were generated with ggplot2 [77].

Supporting information

S1 Table [xlsx]
Summary statistics for analyzing gene expression prediction in SAGE for all seven weight sets in PredictDB.

S2 Table [xlsx]
Summary statistics for each filtering step in the analysis of gene expression models from GEUVADIS for the 3 training populations EUR373, EUR278, and AFR.

S3 Table [xlsx]
SNPs in linkage disequilibrium with rs28450894, on which SAGE RNA-Seq data were ascertained.

S4 Table [xlsx]
R2 between predictions and observations for gene SLC39A8 (Ensembl ID ENSG00000138821).

S5 Table [xlsx]
Summary statistics from training and testing results with continental GEUVADIS populations for gene models with positive correlations.

S6 Table [xlsx]
Spearman correlations between prediction versus simulated measurement from simulated populations to themselves across various shared eQTL proportions for k = 10 causal eQTLs.

S7 Table [xlsx]
Prediction performance under fully shared eQTL architecture for k = 10 eQTLs yields reliable cross-population gene expression prediction.

S8 Table [xlsx]
A Dunn test shows statistically significant differences when predicting between AFR and EUR populations versus predicting between EUR populations.

S9 Table [xlsx]
Differences in cross-population prediction performance are statistically significant, with a few notable exceptions.

S10 Table [xlsx]
Power estimates and 95% confidence intervals for each train-test scenario (Train-Test) and each proportion of YRI (YRI proportion) corresponding to the left panel of for effect size 0.005 (h = 0.06).

S11 Table [xlsx]
Power estimates and 95% confidence intervals for each train-test scenario (Train-Test) and each proportion of YRI (YRI proportion) corresponding to the center panel of for effect size 0.01 (h = 0.20).

S12 Table [docx]
Power estimates and 95% confidence intervals for each train-test scenario (Train-Test) and each proportion of YRI (YRI proportion) corresponding to the right panel of for effect size 0.01 (h = 0.58).

S1 Fig [tiff]
Distributions of log-transformed values of transcripts-per-million (TPM) from GTEx v7.

S2 Fig [tiff]
Distribution of R in SAGE.

S3 Fig [tiff]
Violin plots of R between predictions and measurements in SAGE, with testing R from each PrediXcan repository included for benchmarking.

S4 Fig [tiff]
R of measured gene expression versus predictions from PrediXcan.

S5 Fig [tiff]
A violin plot of the R as shown in .

S6 Fig [tiff]
R in SAGE for all PrediXcan prediction weight sets, similar to , but without testing R from PredictDB.

S7 Fig [tiff]
R between prediction and measurement in SAGE only using the 39 genes with positive correlation between prediction and measurement in all weight sets and benchmarks.

S8 Fig [tiff]
R in SAGE for all PrediXcan prediction weight sets, similar to , but without testing R from PredictDB.

S9 Fig [tiff]
A comparison of R from SAGE and MESA_ALL training diagnostics, similar to .

S10 Fig [tiff]
A comparison of R from SAGE and MESA_AFA training diagnostics, similar to .

S11 Fig [tiff]
A comparison of R from SAGE and MESA_AFHI training diagnostics, similar to .

S12 Fig [tiff]
A comparison of R from SAGE and MESA_CAU training diagnostics, similar to .

S13 Fig [tiff]
Violin plots of the distribution of R from .

S14 Fig [tiff]
Violin plots of the distribution of R from .

S15 Fig [tiff]
Distributions of R across all 25 train-test scenarios using the 5 constituent GEUVADIS populations (CEU, FIN, GBR, TSI, and YRI).

S16 Fig [tiff]
Distributions of R across 142 genes in common to all 25 train-test scenarios.

S17 Fig [tiff]
Prediction R between AFR (YRI) and EUR (CEU, TSI, GBR, and FIN).

S18 Fig [tiff]
Genetic distance versus prediction accuracy over 142 genes with positive correlation across all train-test scenarios.

S19 Fig [tiff]
A schematic of three shared eQTL architectures for the case of k = 10 eQTLs per gene.

S20 Fig [tiff]
Correlations between predictions and simulated gene expression measurements from simulated populations across various proportions of shared eQTL architecture with 20 causal cis-eQTLs.

S21 Fig [tiff]
Correlations between predictions and simulated gene expression measurements from simulated populations across various proportions of shared eQTL architecture with 40 causal cis-eQTLs.

S22 Fig [true]
Mean correlations between predictions and simulated gene expression measurements from simulated populations for a single causal cis-eQTL.

S23 Fig [tiff]
Distributions of t-statistics across various shared eQTL proportions for all nine train-test scenarios with 1000 Genomes populations for a fixed TWAS effect size and fixed number of causal eQTLs.

Zdroje

1. Sudlow C, Gallacher J, Allen N, Beral V, Burton P, Danesh J, et al. UK Biobank: An Open Access Resource for Identifying the Causes of a Wide Range of Complex Diseases of Middle and Old Age. PLoS Med. 2015;12. doi: 10.1371/journal.pmed.1001779 25826379

2. NHLBI Trans-Omics for Precision Medicine. [cited 13 Nov 2018]. Available: https://www.nhlbiwgs.org/

3. NHGRI Genome Sequencing Program (GSP). In: National Human Genome Research Institute (NHGRI) [Internet]. [cited 13 Nov 2018]. Available: https://www.genome.gov/10001691/nhgri-genome-sequencing-program-gsp/

4. The 1000 Genomes Consortium. An integrated map of genetic variation from 1,092 human genomes | Nature. [cited 13 Nov 2018]. Available: https://www.nature.com/articles/nature11632

5. Gusev A, Ko A, Shi H, Bhatia G, Chung W, Penninx BWJH, et al. Integrative approaches for large-scale transcriptome-wide association studies. Nat Genet. 2016;48: 245–252. doi: 10.1038/ng.3506 26854917

6. Gamazon ER, Wheeler HE, Shah KP, Mozaffari SV, Aquino-Michaels K, Carroll RJ, et al. A gene-based association method for mapping traits using reference transcriptome data. Nat Genet. 2015;47: 1091–1098. doi: 10.1038/ng.3367 26258848

7. GTEx Consortium. The Genotype-Tissue Expression (GTEx) project. Nat Genet. 2013;45: 580–585. doi: 10.1038/ng.2653 23715323

8. Battle A, Mostafavi S, Zhu X, Potash JB, Weissman MM, McCormick C, et al. Characterizing the genetic basis of transcriptome diversity through RNA-sequencing of 922 individuals. Genome Res. 2014;24: 14–24. doi: 10.1101/gr.155192.113 24092820

9. Barbeira AN, Dickinson SP, Torres JM, Bonazzola R, Zheng J, Torstenson ES, et al. Exploring the phenotypic consequences of tissue specific gene expression variation inferred from GWAS summary statistics. Nat Commun. 2018;9. doi: 10.1038/s41467-018-03621-1 29739930

10. Zhu Z, Zhang F, Hu H, Bakshi A, Robinson MR, Powell JE, et al. Integration of summary data from GWAS and eQTL studies predicts complex trait gene targets. Nat Genet. 2016;48: 481–487. doi: 10.1038/ng.3538 27019110

11. Mostafavi S, Gaiteri C, Sullivan SE, White CC, Tasaki S, Xu J, et al. A molecular network of the aging human brain provides insights into the pathology and cognitive decline of Alzheimer’s disease. Nat Neurosci. 2018;21: 811. doi: 10.1038/s41593-018-0154-9 29802388

12. Ferreira MAR, Jansen R, Willemsen G, Penninx B, Bain LM, Vicente CT, et al. Gene-based analysis of regulatory variants identifies four putative novel asthma risk genes related to nucleotide synthesis and signaling. J Allergy Clin Immunol. 2017;139: 1148–1157. doi: 10.1016/j.jaci.2016.07.017 27554816

13. Lamontagne M, Bérubé J-C, Obeidat M, Cho MH, Hobbs BD, Sakornsakolpat P, et al. Leveraging lung tissue transcriptome to uncover candidate causal genes in COPD genetic associations. Hum Mol Genet. 2018;27: 1819–1829. doi: 10.1093/hmg/ddy091 29547942

14. Thériault S, Gaudreault N, Lamontagne M, Rosa M, Boulanger M-C, Messika-Zeitoun D, et al. A transcriptome-wide association study identifies PALMD as a susceptibility gene for calcific aortic valve stenosis. Nat Commun. 2018;9: 988. doi: 10.1038/s41467-018-03260-6 29511167

15. Porcu E, Rüeger S, Consortium eQTLGen, Santoni FA, Reymond A, Kutalik Z. Mendelian Randomization integrating GWAS and eQTL data reveals genetic determinants of complex and clinical traits. bioRxiv. 2018; 377267. doi: 10.1101/377267

16. Gusev A, Lawrenson K, Segato F, Fonseca M, Kar S, Lee J, et al. Multi-Tissue Transcriptome-Wide Association Studies Identify 21 Novel Candidate Susceptibility Genes for High Grade Serous Epithelial Ovarian Cancer. bioRxiv. 2018; 330613. doi: 10.1101/330613

17. Huckins LM, Dobbyn A, Ruderfer D, Hoffman G, Wang W, Pardinas AF, et al. Gene expression imputation across multiple brain regions reveals schizophrenia risk throughout development. bioRxiv. 2017; 222596. doi: 10.1101/222596

18. Consortium GTEx. Genetic effects on gene expression across human tissues. Nature. 2017;550: 204–213. doi: 10.1038/nature24277 29022597

19. Bustamante CD, Burchard EG, De la Vega FM. Genomics for the world. Nature. 2011;475: 163–165. doi: 10.1038/475163a 21753830

20. Popejoy AB, Fullerton SM. Genomics is failing on diversity. Nature. 2016;538: 161–164. doi: 10.1038/538161a 27734877

21. Bentley AR, Callier S, Rotimi CN. Diversity and inclusion in genomic research: why the uneven progress? J Community Genet. 2017;8: 255–266. doi: 10.1007/s12687-017-0316-6 28770442

22. Hindorff LA, Bonham VL, Brody LC, Ginoza MEC, Hutter CM, Manolio TA, et al. Prioritizing diversity in human genomics research. Nat Rev Genet. 2018;19: 175–185. doi: 10.1038/nrg.2017.89 29151588

23. Asimit JL, Hatzikotoulas K, McCarthy M, Morris AP, Zeggini E. Trans-ethnic study design approaches for fine-mapping. Eur J Hum Genet. 2016;24: 1330–1336. doi: 10.1038/ejhg.2016.1 26839038

24. Wang X, Cheng C-Y, Liao J, Sim X, Liu J, Chia K-S, et al. Evaluation of transethnic fine mapping with population-specific and cosmopolitan imputation reference panels in diverse Asian populations. Eur J Hum Genet. 2016;24: 592–599. doi: 10.1038/ejhg.2015.150 26130488

25. Li YR, Keating BJ. Trans-ethnic genome-wide association studies: advantages and challenges of mapping in diverse populations. Genome Med. 2014;6: 91. doi: 10.1186/s13073-014-0091-5 25473427

26. Kumar R, Seibold MA, Aldrich MC, Williams LK, Reiner AP, Colangelo L, et al. Genetic ancestry in lung-function predictions. N Engl J Med. 2010;363: 321–330. doi: 10.1056/NEJMoa0907897 20647190

27. Yang JJ, Cheng C, Devidas M, Cao X, Fan Y, Campana D, et al. Ancestry and pharmacogenomics of relapse in acute lymphoblastic leukemia. Nat Genet. 2011;43: 237–241. doi: 10.1038/ng.763 21297632

28. Acuña-Alonzo V, Flores-Dorantes T, Kruit JK, Villarreal-Molina T, Arellano-Campos O, Hünemeier T, et al. A functional ABCA1 gene variant is associated with low HDL-cholesterol levels and shows evidence of positive selection in Native Americans. Hum Mol Genet. 2010;19: 2877–2885. doi: 10.1093/hmg/ddq173 20418488

29. Adeyemo A, Rotimi C. Genetic variants associated with complex human diseases show wide variation across multiple populations. Public Health Genomics. 2010;13: 72–79. doi: 10.1159/000218711 19439916

30. Manrai AK, Funke BH, Rehm HL, Olesen MS, Maron BA, Szolovits P, et al. Genetic Misdiagnoses and the Potential for Health Disparities. N Engl J Med. 2016;375: 655–665. doi: 10.1056/NEJMsa1507092 27532831

31. Petrovski S, Goldstein DB. Unequal representation of genetic variation across ancestry groups creates healthcare inequality in the application of precision medicine. Genome Biol. 2016;17: 157. doi: 10.1186/s13059-016-1016-y 27418169

32. Oh SS, White MJ, Gignoux CR, Burchard EG. Making Precision Medicine Socially Precise. Take a Deep Breath. Am J Respir Crit Care Med. 2016;193: 348–350. doi: 10.1164/rccm.201510-2045ED 26871667

33. Oh SS, Galanter J, Thakur N, Pino-Yanes M, Barcelo NE, White MJ, et al. Diversity in Clinical and Biomedical Research: A Promise Yet to Be Fulfilled. PLoS Med. 2015;12. doi: 10.1371/journal.pmed.1001918 26671224

34. Belbin GM, Nieves-Colón MA, Kenny EE, Moreno-Estrada A, Gignoux CR. Genetic diversity in populations across Latin America: implications for population and medical genetic studies. Curr Opin Genet Dev. 2018;53: 98–104. doi: 10.1016/j.gde.2018.07.006 30125792

35. Martin AR, Gignoux CR, Walters RK, Wojcik GL, Neale BM, Gravel S, et al. Human Demographic History Impacts Genetic Risk Prediction across Diverse Populations. Am J Hum Genet. 2017;100: 635–649. doi: 10.1016/j.ajhg.2017.03.004 28366442

36. Bild DE, Bluemke DA, Burke GL, Detrano R, Diez Roux AV, Folsom AR, et al. Multi-Ethnic Study of Atherosclerosis: objectives and design. Am J Epidemiol. 2002;156: 871–881. doi: 10.1093/aje/kwf113 12397006

37. Liu Y, Ding J, Reynolds LM, Lohman K, Register TC, De La Fuente A, et al. Methylomics of gene expression in human monocytes. Hum Mol Genet. 2013;22: 5065–5074. doi: 10.1093/hmg/ddt356 23900078

38. Mogil LS, Andaleon A, Badalamenti A, Dickinson SP, Guo X, Rotter JI, et al. Genetic architecture of gene expression traits across diverse populations. PLOS Genet. 2018;14: e1007586. doi: 10.1371/journal.pgen.1007586 30096133

39. Mak ACY, White MJ, Eckalbar WL, Szpiech ZA, Oh SS, Pino-Yanes M, et al. Whole-Genome Sequencing of Pharmacogenetic Drug Response in Racially Diverse Children with Asthma. Am J Respir Crit Care Med. 2018;197: 1552–1564. doi: 10.1164/rccm.201712-2529OC 29509491

40. Thakur N, Oh SS, Nguyen EA, Martin M, Roth LA, Galanter J, et al. Socioeconomic status and childhood asthma in urban minority youths. The GALA II and SAGE II studies. Am J Respir Crit Care Med. 2013;188: 1202–1209. doi: 10.1164/rccm.201306-1016OC 24050698

41. Borrell LN, Nguyen EA, Roth LA, Oh SS, Tcheurekdjian H, Sen S, et al. Childhood Obesity and Asthma Control in the GALA II and SAGE II Studies. Am J Respir Crit Care Med. 2013;187: 697–702. doi: 10.1164/rccm.201211-2116OC 23392439

42. Nishimura KK, Galanter JM, Roth LA, Oh SS, Thakur N, Nguyen EA, et al. Early-life air pollution and asthma risk in minority children. The GALA II and SAGE II studies. Am J Respir Crit Care Med. 2013;188: 309–318. doi: 10.1164/rccm.201302-0264OC 23750510

43. Lappalainen T, Sammeth M, Friedländer MR, ‘t Hoen PA, Monlong J, Rivas MA, et al. Transcriptome and genome sequencing uncovers functional variation in humans. Nature. 2013;501: 506–511. doi: 10.1038/nature12531 24037378

44. Sudmant PH, Rausch T, Gardner EJ, Handsaker RE, Abyzov A, Huddleston J, et al. An integrated map of structural variation in 2,504 human genomes. Nature. 2015;526: 75–81. doi: 10.1038/nature15394 26432246

45. Mikhaylova AV, Thornton TA. Accuracy of Gene Expression Prediction From Genotype Data With PrediXcan Varies Across and Within Continental Populations. Front Genet. 2019;10. doi: 10.3389/fgene.2019.00261 31001318

46. Fryett JJ, Morris AP, Cordell HJ. Investigation of prediction accuracy and the impact of sample size, ancestry, and tissue in transcriptome-wide association studies. Genet Epidemiol. 2020;n/a. doi: 10.1002/gepi.22290 32190932

47. Stranger BE, Nica AC, Forrest MS, Dimas A, Bird CP, Beazley C, et al. Population genomics of human gene expression. Nat Genet. 2007;39: 1217–1224. doi: 10.1038/ng2142 17873874

48. Viñuela A, Brown AA, Buil A, Tsai P-C, Davies MN, Bell JT, et al. Age-dependent changes in mean and variance of gene expression across tissues in a twin cohort. Hum Mol Genet. 2018;27: 732–741. doi: 10.1093/hmg/ddx424 29228364

49. McCall MN, Illei PB, Halushka MK. Complex Sources of Variation in Tissue Expression Data: Analysis of the GTEx Lung Transcriptome. Am J Hum Genet. 2016;99: 624–635. doi: 10.1016/j.ajhg.2016.07.007 27588449

50. Zhu Y, Wang L, Yin Y, Yang E. Systematic analysis of gene expression patterns associated with postmortem interval in human tissues. Sci Rep. 2017;7: 5435. doi: 10.1038/s41598-017-05882-0 28710439

51. Ferreira PG, Muñoz-Aguirre M, Reverter F, Godinho CPS, Sousa A, Amadoz A, et al. The effects of death and post-mortem cold ischemia on human tissue transcriptomes. Nat Commun. 2018;9: 490. doi: 10.1038/s41467-017-02772-x 29440659

52. Martin AR, Karczewski KJ, Kerminen S, Kurki MI, Sarin A-P, Artomov M, et al. Haplotype Sharing Provides Insights into Fine-Scale Population History and Disease in Finland. Am J Hum Genet. 2018;102: 760–775. doi: 10.1016/j.ajhg.2018.03.003 29706349

53. Yuan Y, Tian L, Lu D, Xu S. Analysis of Genome-Wide RNA-Sequencing Data Suggests Age of the CEPH/Utah (CEU) Lymphoblastoid Cell Lines Systematically Biases Gene Expression Profiles. Sci Rep. 2015;5: 7960. doi: 10.1038/srep07960 25609584

54. Çalışkan M, Pritchard JK, Ober C, Gilad Y. The Effect of Freeze-Thaw Cycles on Gene Expression Levels in Lymphoblastoid Cell Lines. PLOS ONE. 2014;9: e107166. doi: 10.1371/journal.pone.0107166 25192014

55. The International HapMap 3 Consortium. Integrating common and rare genetic variation in diverse human populations. Nature. 2010;467: 52–58. doi: 10.1038/nature09298 20811451

56. Su Z, Marchini J, Donnelly P. HAPGEN2: simulation of multiple disease SNPs. Bioinformatics. 2011;27: 2304–2305. doi: 10.1093/bioinformatics/btr341 21653516

57. Baharian S, Barakatt M, Gignoux CR, Shringarpure S, Errington J, Blot WJ, et al. The Great Migration and African-American Genomic Diversity. PLOS Genet. 2016;12: e1006059. doi: 10.1371/journal.pgen.1006059 27232753

58. Hoffmann TJ, Zhan Y, Kvale MN, Hesselson SE, Gollub J, Iribarren C, et al. Design and coverage of high throughput genotyping arrays optimized for individuals of East Asian, African American, and Latino race/ethnicity using imputation and a novel hybrid SNP selection algorithm. Genomics. 2011;98: 422–430. doi: 10.1016/j.ygeno.2011.08.007 21903159

59. Das S, Forer L, Schönherr S, Sidore C, Locke AE, Kwong A, et al. Next-generation genotype imputation service and methods. Nat Genet. 2016;48: 1284–1287. doi: 10.1038/ng.3656 27571263

60. Loh P-R, Danecek P, Palamara PF, Fuchsberger C, Reshef YA, Finucane HK, et al. Reference-based phasing using the Haplotype Reference Consortium panel. Nat Genet. 2016;48: 1443–1448. doi: 10.1038/ng.3679 27694958

61. Wheeler HE, Shah KP, Brenner J, Garcia T, Aquino-Michaels K, Consortium Gte, et al. Survey of the Heritability and Sparse Architecture of Gene Expression Traits across Human Tissues. PLOS Genet. 2016;12: e1006423. doi: 10.1371/journal.pgen.1006423 27835642

62. Gravel S. Population genetics models of local ancestry. Genetics. 2012;191: 607–619. doi: 10.1534/genetics.112.139808 22491189

63. Price AL, Tandon A, Patterson N, Barnes KC, Rafaels N, Ruczinski I, et al. Sensitive detection of chromosomal segments of distinct ancestry in admixed populations. PLoS Genet. 2009;5: e1000519. doi: 10.1371/journal.pgen.1000519 19543370

64. Tange O. GNU Parallel 2018. Ole Tange; 2018. doi: 10.5281/zenodo.1146014

65. Shih DJH. argparser: Command-Line Argument Parser. 2016. Available: https://CRAN.R-project.org/package=argparser

66. Wickham H. assertthat: Easy Pre and Post Assertions. 2019. Available: https://CRAN.R-project.org/package=assertthat

67. Dowle M, Srinivasan A, Gorecki J, Chirico M, Stetsenko P, Short T, et al. data.table: Extension of “data.frame.” 2019. Available: https://CRAN.R-project.org/package=data.table

68. Calaway R, Corporation M, Weston S, Tenenbaum D. doParallel: Foreach Parallel Adaptor for the “parallel” Package. 2018. Available: https://CRAN.R-project.org/package=doParallel

69. Dinno A. dunn.test: Dunn’s Test of Multiple Comparisons Using Rank Sums. 2017. Available: https://CRAN.R-project.org/package=dunn.test

70. Xie Y, Vogt A, Andrew A, Zvoleff A, http://www.andre-simon.de) AS (the C files under inst/themes/ were derived from the H package, Atkins A, et al. knitr: A General-Purpose Package for Dynamic Report Generation in R. 2019. Available: https://CRAN.R-project.org/package=knitr

71. Davis TL, package.) AD (Some documentation and examples ported from the getopt, module.) PSF (Some documentation from the optparse P, Lianoglou S, Nikelski J, Müller K, et al. optparse: Command Line Option Parser. 2019. Available: https://CRAN.R-project.org/packa=optparsege

72. Gentleman R. annotate: Annotation for microarrays. 2018. Available: http://bioconductor.org/packages/annotate/

73. Durinck S, Moreau Y, Kasprzyk A, Davis S, De Moor B, Brazma A, et al. BioMart and Bioconductor: a powerful link between biological databases and microarray data analysis. Bioinforma Oxf Engl. 2005;21: 3439–3440. doi: 10.1093/bioinformatics/bti525 16082012

74. Durinck S, Spellman PT, Birney E, Huber W. Mapping identifiers for the integration of genomic datasets with the R/Bioconductor package biomaRt. Nat Protoc. 2009;4: 1184–1191. doi: 10.1038/nprot.2009.97 19617889

75. Bolstad B. preprocessCore. 2017. Available: https://github.com/bmbolstad/preprocessCore

76. Wickham, Hadley, Grolemund, Garrett. R for Data Science. O’Reilly Media, Inc.; 2017. Available: https://r4ds.had.co.nz/

77. Wickham Hadley. ggplot2: Elegant Graphics for Data Analysis. Springer-Verlag New York; 2016. Available: http://ggplot2.org.

Článek Immediate activation of chemosensory neuron gene expression by bacterial metabolites is selectively induced by distinct cyclic GMP-dependent pathways in Caenorhabditis elegans

Článek Gα/GSA-1 works upstream of PKA/KIN-1 to regulate calcium signaling and contractility in the Caenorhabditis elegans spermatheca

Článek Mutation of CFAP57, a protein required for the asymmetric targeting of a subset of inner dynein arms in Chlamydomonas, causes primary ciliary dyskinesia

Článek Transcriptional regulators of the Golli/myelin basic protein locus integrate additive and stealth activities

Článek DAnkrd49 and Bdbt act via Casein kinase Iε to regulate planar polarity in Drosophila

Článek Mapping gene flow between ancient hominins through demography-aware inference of the ancestral recombination graph

Článek Endogenization and excision of human herpesvirus 6 in human genomes

Článek A subset of broadly responsive Type III taste cells contribute to the detection of bitter, sweet and umami stimuli

Článek How many familial relationship testing results could be wrong?