Power of Inclusion: enhancing polygenic prediction with admixed individuals

Tanigawa and Kellis. Am J Hum Genet. (2023).

Phenotype: Lymphocyte count

Link to the source data field in UK Biobank
Estimated h² in white British population in UKB: 0.052 (95% CI:[0.044, 0.060]).
Link to PGS catalog (Study ID: PGP000502).
GWAS Catalog for mapped trait(s): lymphocyte count (EFO_0004587)

Our FAQ page shows the description of the file format and how you may use iPGS coefficients in your research.

iPGS prediction in the held-out test set individuals

We compared the polygenic prediction from our iPGS model and the phenotype values using the held-out test set individuals in UK Biobank. Note the difference in the number of individuals in the five population groups.

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/static/data/tanigawakellis2023/per_trait/INI30120/INI30120.Afr.PGS_vs_phe.png

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Predictive performance

Population	Model	Metric	Predictive Performance	95% CI	P-value
Population	Model	Metric	Predictive Performance	95% CI	P-value

white British	Covariate-only model	R²	0.006	[0.004, 0.007]	2.6x10^-82
white British	Genotype-only model	R²	0.022	[0.020, 0.024]	1.9x10^-308
white British	Full model (covariates and genotypes)	R²	0.027	[0.025, 0.030]	<1.0x10^-300
Non-British white	Covariate-only model	R²	0.007	[0.001, 0.014]	5.1x10^-06
Non-British white	Genotype-only model	R²	0.027	[0.015, 0.039]	1.9x10^-18
Non-British white	Full model (covariates and genotypes)	R²	0.034	[0.021, 0.047]	8.8x10^-23
South Asian	Covariate-only model	R²	0.020	[0.006, 0.034]	1.0x10^-07
South Asian	Genotype-only model	R²	0.042	[0.022, 0.062]	4.1x10^-15
South Asian	Full model (covariates and genotypes)	R²	0.059	[0.036, 0.082]	1.3x10^-20
African	Covariate-only model	R²	0.024	[0.007, 0.040]	1.7x10^-07
African	Genotype-only model	R²	0.006	[-0.003, 0.014]	1.2x10^-02
African	Full model (covariates and genotypes)	R²	0.019	[0.004, 0.034]	3.4x10^-06
Others	Covariate-only model	R²	0.021	[0.015, 0.027]	3.2x10^-37
Others	Genotype-only model	R²	0.029	[0.022, 0.036]	2.4x10^-51
Others	Full model (covariates and genotypes)	R²	0.047	[0.038, 0.056]	9.4x10^-83

The predictive performance (R²), its 95% confidence interval (CI), and statistical significance (P-value) are shown for each population in UK Biobank in the held-out test set. The "model" column indicates whether the predictive performance is from the covariate-terms alone (covariate-only model), PGS terms alone (Genotype-only model), or the full model containing both PGS and covariate terms. We used the following sets of covariates in our analysis: age, sex, age², age*sex, Townsend deprivation index, and genotype PCs (PC1-PC18). Please refer to our publication for a more detailed description of the methods.

Coefficients (BETA) of PGS models

/static/data/tanigawakellis2023/per_trait/INI30120/INI30120.BETAs.png

We show the coefficients (BETA) of PGS models. Our iPGS model selected 7291 variants with non-zero coefficients. The genetic variants with the large absolute values of coefficients are annotated in the plot. There is no guarantee that our iPGS model selects causal variants. We use the GRCh37/hg19 reference genome.

The top 100 genetic variants with the largest absolute value of coefficients

CHROM	POS	Variant	Variant ID	Effect allele	Consequence	Gene symbol	Beta
CHROM	POS	Variant	Variant ID	Effect allele	Consequence	Gene symbol	Beta

12	111884608	12:111884608:T:C	rs3184504	C	PAVs	SH2B3	-0.042
19	16527834	19:16527834:T:C	rs4808047	C	Intronic	EPS15L1	0.032
1	114377568	1:114377568:A:G	rs2476601	G	PAVs	PTPN22	0.022
5	35876274	5:35876274:A:G	rs3194051	G	PAVs	IL7R	0.021
22	21982892	22:21982892:C:T	rs2298428	T	PAVs	YDJC	-0.021
7	45004063	7:45004063:T:C	rs7792760	C	PAVs	MYO1G	0.020
12	6502131	12:6502131:T:G	rs2364482	G	Others	RP1-102E24.8	0.019
9	21973422	9:21973422:G:T	rs2811708	T	Intronic	RP11-145E5.5, CDKN2A	-0.018
4	38330855	4:38330855:C:T	rs13139166	T	Others		0.017
3	12267648	3:12267648:A:G	rs7616006	G	Others		-0.016
16	84581768	16:84581768:C:T	rs247832	T	Intronic	TLDC1	0.016
19	16442782	19:16442782:C:T	rs34006614	T	Others	KLF2	-0.016
13	74705251	13:74705251:C:T	rs9600237	T	Intronic	KLF12	0.016
11	123361397	11:123361397:G:A	rs735665	A	Others		0.015
4	103557077	4:103557077:G:A	rs2866413	A	PAVs	MANBA	0.014
6	42024285	6:42024285:G:A	rs10948011	A	Intronic	TAF8	0.014
13	114830132	13:114830132:C:T	rs7986001	T	Intronic	RASA3	-0.014
15	91011262	15:91011262:A:G	rs2238325	G	Intronic	IQGAP1	0.013
3	39307162	3:39307162:G:A	rs3732378	A	PAVs	CX3CR1	0.013
6	24806594	6:24806594:C:T	rs9358799	T	PTVs	FAM65B	-0.013
6	31319355	6:31319355:G:T	rs2442728	T	Others	HLA-B	-0.013
2	25491056	2:25491056:A:G	rs7583409	G	Intronic	DNMT3A	0.013
16	30493881	16:30493881:T:C	rs11150590	C	Intronic	RP11-297C4.2, ITGAL	0.013
17	2001825	17:2001825:T:C	rs7225843	C	Intronic	SMG6, RP11-667K14.5	-0.013
2	181981055	2:181981055:G:A	rs6706696	A	Intronic	AC104820.2	-0.013
19	1079959	19:1079959:G:A	rs36084354	A	PAVs	HMHA1	-0.013
8	79572222	8:79572222:C:A	rs1384804	A	Others		-0.013
20	1922283	20:1922283:T:G	rs6112072	G	Others	SIRPA	-0.013
6	32552086	HLA-DRB1*0101	HLA-DRB1*0101	+	PAVs	HLA-DRB1	0.012
6	31238217	HLA-C*0401	HLA-C*0401	+	PAVs	HLA-C	0.012
3	46988561	3:46988561:C:T	rs13092573	T	Intronic	CCDC12	0.012
19	10395683	19:10395683:A:G	rs5498	G	PAVs	ICAM1	-0.012
2	143798189	2:143798189:A:G	rs9013	G	PAVs	KYNU	-0.012
2	182199917	2:182199917:C:A	rs2218160	A	Intronic	AC104820.2	0.012
6	31106501	6:31106501:C:CC	Affx-89026413	CC	PTVs	PSORS1C1	0.012
19	10475652	19:10475652:C:A	rs2304256	A	PAVs	TYK2	0.012
3	46450072	3:46450072:G:A	rs6441977	A	PAVs	CCRL2	0.012
12	9885707	12:9885707:A:ATAAGT	rs71045297	ATAAGT	PTVs	CLECL1	0.012
2	188343497	2:188343497:T:C	rs7586970	C	PAVs	TFPI	-0.012
14	35834558	14:35834558:C:T	rs11621391	T	Others	RP11-561B11.3	-0.012
17	72700943	17:72700943:A:G	rs35489971	G	PAVs	CD300LF	0.012
17	4608622	17:4608622:T:C	rs7215300	C	Others	RP11-314A20.2	-0.011
2	24245659	2:24245659:C:T	rs17712391	T	Intronic	MFSD2B	0.011
20	8607393	20:8607393:G:A	rs4432538	A	Intronic	PLCB1	-0.011
12	9910164	12:9910164:G:A	rs4763879	A	Intronic	CD69	-0.011
12	9923113	12:9923113:T:C	rs724666	C	Others		-0.011
2	227291415	2:227291415:A:C	rs11686139	C	Others		0.011
13	74675573	13:74675573:T:C	rs2104388	C	Intronic	KLF12	-0.011
15	56756285	15:56756285:T:G	rs1715919	G	PAVs	MNS1	0.010
6	135419018	6:135419018:T:C	rs9399137	C	Intronic	HBS1L	-0.010
2	111599706	2:111599706:G:A	rs4849121	A	Intronic	ACOXL	0.010
X	153220360	X:153220360:A:G	rs1051152	G	PAVs	HCFC1	-0.010
4	38604807	4:38604807:T:C	rs337638	C	Others		0.010
6	31237124	6:31237124:T:C	rs1130838	C	PAVs	HLA-C	0.010
11	122520253	11:122520253:T:C	rs1945390	C	Others		0.010
12	12879254	12:12879254:T:G	rs7956514	G	PAVs	APOLD1	0.010
2	43732823	2:43732823:T:C	rs7578597	C	PAVs	THADA	-0.010
19	13942221	19:13942221:A:G	rs3745453	G	UTR	ZSWIM4	0.010
8	78643619	8:78643619:T:C	rs17385111	C	Others		0.010
17	2883588	17:2883588:C:A	rs17762452	A	PAVs	RAP1GAP2	-0.010
6	411064	6:411064:A:G	rs872071	G	UTR	IRF4	0.010
6	31506691	6:31506691:G:A	rs2071596	A	PAVs	DDX39B	-0.010
1	101235841	1:101235841:A:G	rs1409423	G	Others		0.010
X	3664074	X:3664074:T:C	rs6641876	C	Others		-0.010
3	27757018	3:27757018:G:T	rs2371108	T	Others	EOMES, RP11-222K16.2	0.010
14	103342049	14:103342049:T:C	rs1131877	C	PAVs	TRAF3	0.010
16	88849421	16:88849421:A:G	rs2608604	G	Intronic	PIEZO1	-0.010
4	83503020	4:83503020:C:A	rs4693460	A	Others	RP11-791G16.4	-0.010
6	108053364	6:108053364:G:A	rs12526696	A	UTR	SCML4	0.010
19	14153293	19:14153293:T:C	rs35026308	C	PAVs	IL27RA	0.009
1	67470843	1:67470843:C:T	rs2755253	T	Intronic	SLC35D1	-0.009
5	2555514	5:2555514:A:C	rs10475169	C	Others		0.009
9	22142907	9:22142907:G:A	rs10811664	A	Others		-0.009
19	44278779	19:44278779:T:G	rs649540	G	PAVs	KCNN4	0.009
5	150518357	5:150518357:C:CG	rs34624580	CG	PAVs	ANXA6	-0.009
6	34217181	6:34217181:C:A	rs1150777	A	UTR	C6orf1	0.009
19	47679798	19:47679798:T:C	rs466477	C	Intronic	SAE1	-0.009
22	29037864	22:29037864:C:A	rs9625520	A	Intronic	TTC28	-0.009
3	151033597	3:151033597:A:C	rs6767266	C	Intronic	MED12L, GPR87	0.009
19	16449517	19:16449517:C:T	rs1000329	T	Others		-0.009
12	9897434	12:9897434:G:A	rs10772104	A	Others		0.009
9	137768979	9:137768979:T:C	rs4372082	C	Others	FCN2	-0.009
6	53130081	6:53130081:C:T	rs2057024	T	Others	ELOVL5	0.009
9	35711806	9:35711806:G:T	rs2249250	T	PAVs	TLN1	-0.009
2	161292387	2:161292387:T:C	rs13429951	C	Intronic	RBMS1	-0.008
17	4638563	17:4638563:G:A	rs2277680	A	PAVs	CXCL16	-0.008
8	129007207	8:129007207:A:G	rs10956403	G	Intronic	PVT1	-0.008
4	38109847	4:38109847:T:C	rs1344603	C	Intronic	TBC1D1	0.008
20	1930704	20:1930704:C:T	rs4470399	T	Intronic	RP4-684O24.5	-0.008
14	66953534	14:66953534:G:A	rs7147360	A	PAVs	LINC00238	0.008
4	38314170	4:38314170:A:G	rs1586459	G	Others		0.008
1	25251424	1:25251424:G:A	rs742230	A	Intronic	RUNX3	0.008
17	42339303	17:42339303:G:T	rs2074106	T	Intronic	SLC4A1, AC003043.1	0.008
3	16327855	3:16327855:T:G	rs842274	G	PAVs	OXNAD1	0.008
9	123648085	9:123648085:A:G	rs10818482	G	Others		0.008
6	44586363	6:44586363:C:T	rs6913259	T	Others		-0.008
1	160793560	1:160793560:A:G	rs509749	G	PAVs	LY9	0.008
11	60173360	11:60173360:A:G	rs4938941	G	PTVs	MS4A14	0.008
9	86549939	9:86549939:C:A	rs10124390	A	Others	C9orf64	-0.008
2	43632200	2:43632200:G:A	rs6714067	A	Intronic	THADA	-0.008

There is no guarantee that our iPGS model selects causal variants. We show the top 100 variants with the largest effect size (BETA). To see 7291 variants included in our iPGS model, please download the iPGS coefficients by clicking the download button. We use the GRCh37/hg19 reference genome.

Follow-up analysis

There are several ways to use the resource in your research. First, you may use our iPGS coefficients and compute individual-level polygenic scores for your cohort. Second, you may also investigate the genetic variants with non-zero coefficients and their annotated genes to learn more about biology by taking advantage of the sparsity of our iPGS models. For your convenience, here we suggest several resources as an example of follow-up analysis. We do not intend to cover all the relevant follow-up analyses.

Using iPGS coefficients

By clicking the download button above, you may download the iPGS coefficients. Our FAQ page shows the description of file format and how you may use iPGS coefficients in your research.

HaploReg

HaploReg is a tool for exploring annotations of the non-coding genome at variants on haplotype blocks. The button above submits the top 100 genetic variants with the largest absolute value of coefficients as a query to HaploReg using the default parameters in HaploReg v4.2 (LD threshold r² >= 1, ChromHMM 15-state model, SiPhy-omega, and GENCODE genes). HaploReg's ability to browse haplotypes is useful here as there is no guarantee that our iPGS model selects causal variants. The 'top 100 variant' cutoff is an arbitrary threshold; we aim to demonstrate how one may investigate the selected variants. Please check Ward and Kellis. Nucleic Acids Res. 2012 and Ward and Kellis. Nucleic Acids Res. 2016 for more information on HaploReg.

GREAT

GREAT: Genomic Regions Enrichment of Annotations Tool evaluates enrichment of pathway and ontology terms. The ability of GREAT to map non-coding genetic variants to their downstream target genes would be suitable for investigating pathway and ontology enrichment of genetic variants selected in our sparse iPGS model. The button above submits the top 1000 genetic variants with the largest absolute value of coefficients as a query to GREAT using the default parameters in GREAT v4.0.4. The 'top 1000 variant' cutoff is an arbitrary threshold; we aim to demonstrate how one may investigate the selected variants. Please check McLean et al. Nat Biotechnol. 2010 and Tanigawa*, Dyer*, and Bejerano. PLoS Comput Biol. 2022 for more information on GREAT.

References

Y. Tanigawa and M. Kellis. Power of inclusion: Enhancing polygenic prediction with admixed individuals. Am J Hum Genet. (2023).
- We introduce our inclusive PGS approach in this publication.
- Supplementary Data Files at figshare (doi: 10.6084/m9.figshare.22905368)
- MIT News article: Making genetic prediction models more inclusive
- Author interview: Inside AJHG: A Chat with Yosuke Tanigawa
J. Qian, Y. Tanigawa, W. Du, M. Aguirre, C. Chang, R. Tibshirani, M. A. Rivas, T. Hastie. A fast and scalable framework for large-scale and ultrahigh-dimensional sparse regression with application to the UK Biobank. PLoS Genet. 16, e1009141 (2020).
- In iPGS, we fit penalized multivariate regression on individual-level data using the BASIL algorithm implemented in the R snpnet package. This publication describes the BASIL algorithm and the R snpnet package.