Abstract
Structural variants and presence/absence polymorphisms are common in plant genomes, yet they are routinely overlooked in genome-wide association studies (GWAS). Here, we expand the type of genetic variants detected in GWAS to include major deletions, insertions and rearrangements. We first use raw sequencing data directly to derive short sequences, k-mers, that mark a broad range of polymorphisms independently of a reference genome. We then link k-mers associated with phenotypes to specific genomic regions. Using this approach, we reanalyzed 2,000 traits in Arabidopsis thaliana, tomato and maize populations. Associations identified with k-mers recapitulate those found with SNPs, but with stronger statistical support. Importantly, we discovered new associations with structural variants and with regions missing from reference genomes. Our results demonstrate the power of performing GWAS before linking sequence reads to specific genomic regions, which allows the detection of a wider range of genetic variants responsible for phenotypic variation.
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Data availability
A list of all phenotypes and top SNPs or k-mers passing their corresponding thresholds can be found at https://zenodo.org/record/3701176#.XmX9u5NKhhE.
The authors declare that all other data supporting the findings of this study are available within the Supplementary Information files.
Code availability
Code is available at https://github.com/voichek/kmersGWAS.
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Acknowledgements
We thank the many colleagues who have shared A. thaliana phenotypic information with us. We thank in particular G. Zhu and S. Huang for help with tomato genotypic and phenotypic information and C. Romay, R. Bukowski and E. Buckler for help with maize genotypes and phenotypes. We thank K. Swarts, F. Rabanal and I. Soifer for fruitful discussions. This work was supported by the DFG ERA-CAPS 1001 Genomes Plus and the Max Planck Society.
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Y.V. and D.W. designed the study and wrote the paper. Y.V. conducted the analysis.
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Extended data
Extended Data Fig. 1 Examples of well characterized structural variant tagged by k-mers.
Examples of how k-mers tag well characterized structural variants22 between the Col-0 reference genome and the Ler fully assembled genome. The two genomes were used to count 31 bp k-mers, and all k-mers unique to one genome and appearing only once in it were plotted in the indicated regions. The a translocation, b inversion and c-d insertion/deletion positions are indicated by vertical lines and red shades. The k-mers unique to Col-0/Ler are plotted in the upper/lower panels in red/blue, respectively. The five positions tagged by k-mers inside the translocation presented in a are either SNPs or 1 bp indels.
Extended Data Fig. 2 Genome-wide evaluation of k-mer potential to detect SVs in well-characterized genomes.
a, For every translocation or inversion, previously identified22 between the Col-0 reference genome or the Ler genome we evaluate if it is tagged by 31 bp k-mers. Each translocation or inversion will affect 4 edges between the translocated fragment and the neighbouring genomic regions (bottom panel). For every previously identified translocation or inversion, the number of edges (0-4) which are tagged by k-mers unique to one genome were counted. Only 1.1% of these SVs were not tagged by any k-mer unique to one genome (upper panel). b, For every edge tagged by k-mers, described in A, we plot the number of k-mers unique to one genome which tagged it. The histogram is enriched with edges covered by the maximal number of k-mers, 31. c, Evaluating the potential to tag by k-mers long insertions/deletions between the well characterized genomes of Col-0 and Ler22. While in the genome with the apparent deletion only the junction between the two fragments will be tagged by unique k-mers, in the genome with the apparent insertion, the entire insert will be tagged (bottom panel). Only 0.4% of the previously characterized long insertions/deletions are not tagged by unique k-mers.
Extended Data Fig. 3 Pipeline for k-mer-based GWAS.
a, Creating the k-mer presence/absence table: Each accession’s genomic DNA sequencing reads are cut into k-mers45, filtering k-mers appearing less than twice/thrice in a sequencing library. k-mers are further filtered to retain only those present in at least 5 accessions, and ones that are found in both forward and reverse-complement form in at least 20% of accessions they appeared in. All k-mer lists are combined into a k-mer presence/absence table. b, Genome-wide associations on the full k-mers table using SNP-based software: the k-mers table is converted into PLINK binary format, which is used as input for SNP-based association mapping software14,42. c, GWA optimized for the k-mers: k-mers presence/absence patterns are first associated with the phenotype and its permutations using a LMM to account for population structure16,17. This first step is done by calculating an approximated score of the exact model. Best k-mers from this first step (for example 100,000 k-mers) are passed to the second step, In which an exact p-value is calculated14 for both the phenotype and its permutations. A permutation-based threshold is calculated, and all k-mers passing this threshold are checked for their rank in the scoring from the first step. If not all k-mers hits are in the top 50% of the initial scoring, then the entire process is rerun from the beginning, passing more k-mers from the first to the second step. This last test is built to confirm that the approximation of the first step will not remove true associated k-mers.
Extended Data Fig. 4 Allele counts for A. thaliana 1001G k-mers.
Histogram of k-mer allele counts: For every N=1..1008, the number of k-mers appeared in exactly N accessions is plotted.
Extended Data Fig. 5 Flowering time-genotype associations in A. thaliana identified with k-mers.
a, LD between SNPs associated with flowering time. Dashed lines represent the four variant types, as in Fig. 1c. b, LD between k-mers associated with flowering time, Dashed lines represent the four variant types, as in Fig. 1c. c, Same as Fig. 1d with only SNPs. d, Same as Fig. 1d with only k-mers presented, showing also k-mers lower than the threshold. e, Manhattan plot of SNPs and k-mer associations with flowering time in 10 °C as in Fig. 1d for k-mers of length 25 bp.
Extended Data Fig. 6 Comparison of SNP- and k-mer-GWAS on phenotypes from 104 studies on A. thaliana accessions.
a, Histogram of the number of identified k-mers vs. identified SNPs (in log2) for A. thaliana phenotypes. Only the 458 phenotypes with both variant types identified were used. b, Histogram of thresholds difference of k-mers vs. SNPs of all A. thaliana phenotypes. Thresholds were -log10 transformed.
Extended Data Fig. 7 Specific case studies in which k-mers are superior to SNPs.
a, Results from GWAS on measurements of lesions by Botrytis cinerea UKRazz strain39. An example of k-mers having better hold on a short variant: 19 k-mers and no SNPs were identified, all k-mers in complete LD (top row). Sequence reads containing the k-mers mapped to chromosome 3, with a single T nucleotide deletion out of an eight T’s stretch, in position 72,017. Manual (middle) and the 1001G project (bottom) calls are shown. In the 1001G, 57 of 61 accessions contain missing values. b, Haplotypes around SNPs associated with xylosides concentrations are not correlated with this trait. All SNPs in positions 870,000 to 874,000 in chromosome 5 were hierarchically clustered (left panel, white mark missing values). The two identified SNPs are marked by arrows and a close-up of their state is shown (middle panel). Phenotypic values colored according to the two SNPs: TG blue, TT red, and CT green (right panel). c-e, Manhattan plot for: c, xyloside percentage, d, seedling growth inhibition by a flg22 variant, e, germination in darkness in low nutrient conditions. f, Germination phenotype plotted for accessions with top associated k-mer present or absent. Boxes cover 25%- 75% percentiles, medians marked by horizontal lines, and whiskers cover the full range of values.
Extended Data Fig. 8 Comparison of SNP- and k-mer- based GWAS in maize.
a, Histogram of k-mer allele counts for maize accessions. b, Histogram of difference between threshold values of SNPs and k-mers for maize phenotypes. c, Histogram of the top SNP P-value divided by the k-mers defined threshold, in (-log10), for maize phenotypes. Plotted for phenotypes with only identified SNPs (upper panel) or for phenotypes with both SNPs and k-mers identified (lower panel). d, Histogram of the number of identified k-mers vs. identified SNPs for maize phenotypes. e, Histogram of the difference between top (-log10) p-values in the two methods for maize phenotypes identified by both methods. Plotted as in Fig. 2g. f, Manhattan plot of associations with ear weight (environment 07A). Associated k-mers could not be located in the reference genome, and are thus not presented.
Extended Data Fig. 9 Comparison of SNP- and k-mer-based GWAS in tomato.
a, Histogram of k-mers allele counts for tomato accessions. b, Histogram of difference between threshold values of SNPs and k-mers for tomato phenotypes. c, Histogram of the top SNP P-value divided by the k-mers defined threshold, in -log10, for tomato phenotypes. Plotted for phenotypes with only identified SNPs (upper panel) or for phenotypes with both SNPs and k-mers identified (lower panel). d, Histogram of the difference between top (-log10) p-values in the two methods for tomato phenotypes. e, Histogram of the number of identified k-mers vs. identified SNPs for tomato phenotypes.
Extended Data Fig. 10 Kinship matrix calculation based on k-mers for tomato accessions.
Identification of pairs of tomato accessions for which relatedness as measured with k-mers is much lower than relatedness as measured with SNPs. For every pair among the 246 accessions, a black square is plotted if the difference in relatedness between SNPs and k-mers is larger than 0.15. Accessions are ordered by the number of black square in their row/column. Red lines mark the 21 accessions with most black squares, that is, those for which the k-mer/SNP difference in relatedness is larger than 0.15 for the most pairs.
Supplementary information
Supplementary Information
Supplementary Figs. 1 and 2, Supplementary Note and Supplementary Tables 2 and 3
Supplementary Table 1
Summarized genome-wide association analysis results for phenotypes used in this study.
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Voichek, Y., Weigel, D. Identifying genetic variants underlying phenotypic variation in plants without complete genomes. Nat Genet 52, 534–540 (2020). https://doi.org/10.1038/s41588-020-0612-7
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DOI: https://doi.org/10.1038/s41588-020-0612-7
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