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Selective sweep and GWAS provide insights into adaptive variation of Populus cathayana leaves

  • # Authors contributed equally: Xinglu Zhou, Xiaodong Xiang

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  • Received: 14 December 2023
    Revised: 25 February 2024
    Accepted: 19 March 2024
    Published online: 09 April 2024
    Forestry Research  4 Article number: e012 (2024)  |  Cite this article
  • Leaf morphology plays a crucial role in predicting the productivity and environmental adaptability of forest trees, making it essential to understand the genetic mechanisms behind leaf variation. In natural populations of Populus cathayana, leaf morphology exhibits rich intraspecific variation due to long-term selection. However, there have been no studies that systematically reveal the genetic mechanisms of leaf variation in P. cathayana. To fill this gap and enhance our understanding of leaf variation in P. cathayana, we collected nine leaf traits from the P. cathayana natural population, consisting of 416 accessions, and conducted the preliminary classification of leaf types with four categories. Subsequently, we conducted an analysis of selective sweep and genome-wide association studies (GWAS) to uncover the genetic basis of leaf traits variation. Most of the leaf traits displayed significant correlations, with broad-sense trait heritability ranging from 0.38 to 0.74. In total, three selective sweep methods ultimately identified 278 positively selected candidate regions and 493 genes associated with leaf size. Single-trait and multi-trait GWAS methods detected 13 and 59 genes, respectively. By integrating the results of selective sweep and GWAS, we further identified a total of nine overlapping genes. These genes may play a role in the leaf development process and are closely associated with leaf size. In particular, the gene CBSCBSPB3 (Pca07G009100) located on chromosome 7, was associated with the response to light stimulation. This study will deepen our understanding of the genetic mechanism of leaf adaptive variation in P. cathayana and provide valuable gene resources.
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  • Supplemental Table S1 The statistical results of nine leaf traits of each P. cathayana genotype.
    Supplemental Table S2 List of P. cathayana leaf traits and GWAS parameters.
    Supplemental Table S3 The information of the first three principal components in the PCA analysis of the genotype data.
    Supplemental Table S4 Genetic relationship matrix of genotypes in the P. cathayana population.
    Supplemental Table S5 List of traits used for multitrait associations in P. cathayana.
    Supplemental Table S6 Statistical information on leaf traits of four leaf categories.
    Supplemental Table S7 Information on candidate genes identified by the three selective sweep methods.
    Supplemental Table S8 GO enrichment analysis of selective sweep condidate genes.
    Supplemental Table S9 KEGG enrichment analysis of selective sweep condidate genes.
    Supplemental Table S10 Statistical information of significantly associated SNPs identified by multi-trait GWAS.
    Supplemental Table S11 Annotation information of GWAS candidate genes.
    Supplemental Table S12 Statistical results and PVE of suggestive association SNPs.
    Supplemental Table S13 Annotation information of key candidate genes.
    Supplemental Table S14 GO enrichment analysis of GWAS candidate genes.
    Supplemental Table S15 KEGG enrichment analysis of GWAS candidate genes.
    Supplemental Table S16 Candidate gene network visualization.
    Supplemental Table S17 The functional annotation information of overlapping genes between selective sweep and GWAS.
    Supplemental Fig. S1    Phylogenetic tree and population structure of P. cathayana populations[34]. Each individual is denoted by a vertical bar composed of different colors corresponding to its proportion of genetic ancestry.
    Supplemental Fig. S2 Manhattan plots GEMMA single-trait GWAS in P. cathayana. P-values were transformed into log10 (p). Each dot represents a single nucleotide polymorphism (SNP), and SNPs above green lines passed bonferroni correction test (p ≤8.51 × 108), while SNPs above grey lines are considered suggestive associations (p ≤ 1.70 × 10−6).
    Supplemental Fig. S3 QQ plot for single-trait GWAS analysis, corresponding to the manhattan plots for single-trait GWAS.
    Supplemental Fig. S4 QQ plot for multi-trait GWAS analysis. The plots (a, b, c, d, and e) correspond to the QQ plots of LA_LP_LL_LW, LA_PL_SPAD, LI_LW_LL, LMF_LA_LP and RPL_LI_LMF, respectively.
    Supplemental Fig. S5 Functional enrichment analysis of GWAS candidate genes. a: GO enrichment analysis of candidate genes, where the size of the points represents the number of genes, and the color of the points indicates significance level. BP, CC, MF respectively represent biological process, cellular component, and molecular function. b: KEGG enrichment analysis of candidate genes, where the size of the points represents the number of genes, and the color of the points indicates significance level.
  • [1]

    Tsukaya H. 2005. Leaf shape: genetic controls and environmental factors. The International Journal of Developmental Biology 49:547−55

    doi: 10.1387/ijdb.041921ht

    CrossRef   Google Scholar

    [2]

    Tsukaya H. 2013. Leaf development. The Arabidopsis Book 2013:e0163

    doi: 10.1199/tab.0163

    CrossRef   Google Scholar

    [3]

    Li L, Jin Z, Huang R, Zhou J, Song F, et al. 2023. Leaf physiology variations are modulated by natural variations that underlie stomatal morphology in Populus. Plant, Cell & Environment 46:150−70

    doi: 10.1111/pce.14471

    CrossRef   Google Scholar

    [4]

    Chhetri HB, Macaya-Sanz D, Kainer D, Biswal AK, Evans LM, et al. 2019. Multitrait genome-wide association analysis of Populus trichocarpa identifies key polymorphisms controlling morphological and physiological traits. New Phytologist 223:293−309

    doi: 10.1111/nph.15777

    CrossRef   Google Scholar

    [5]

    Sork VL, Aitken SN, Dyer RJ, Eckert AJ, Legendre P, et al. 2013. Putting the landscape into the genomics of trees: approaches for understanding local adaptation and population responses to changing climate. Tree Genetics & Genomes 9:901−11

    doi: 10.1007/s11295-013-0596-x

    CrossRef   Google Scholar

    [6]

    Anderson JT, Willis JH, Mitchell-Olds T. 2011. Evolutionary genetics of plant adaptation. Trends in Genetics 27:258−66

    doi: 10.1016/j.tig.2011.04.001

    CrossRef   Google Scholar

    [7]

    Omori M, Yamane H, Osakabe K, Osakabe Y, Tao R. 2021. Targeted mutagenesis of CENTRORADIALIS using CRISPR/Cas9 system through the improvement of genetic transformation efficiency of tetraploid highbush blueberry. The Journal of Horticultural Science and Biotechnology 96:153−61

    doi: 10.1080/14620316.2020.1822760

    CrossRef   Google Scholar

    [8]

    Chhetri HB, Furches A, Macaya-Sanz D, Walker AR, Kainer D, et al. 2020. Genome-wide association study of wood anatomical and morphological traits in Populus trichocarpa. Frontiers in Plant Science 11:545748

    doi: 10.3389/fpls.2020.545748

    CrossRef   Google Scholar

    [9]

    Mähler N, Schiffthaler B, Robinson KM, Terebieniec BK, Vučak M, et al. 2020. Leaf shape in Populus tremula is a complex, omnigenic trait. Ecology and Evolution 10:11922−40

    doi: 10.1002/ece3.6691

    CrossRef   Google Scholar

    [10]

    Garot E, Dussert S, Domergue F, Joët T, Fock-Bastide I, et al. 2021. Multi-approach analysis reveals local adaptation in a widespread forest tree of Reunion Island. Plant and Cell Physiology 62:280−92

    doi: 10.1093/pcp/pcaa160

    CrossRef   Google Scholar

    [11]

    Zhou Q, Shen X, Li Y. 2022. Variation pattern and genome-wide association study of leaf phenotypic traits among ancient Ginkgo biloba L. populations. Forests 13:1764

    doi: 10.3390/f13111764

    CrossRef   Google Scholar

    [12]

    Chen Y, Niu S, Deng X, Song Q, He L, et al. 2023. Genome-wide association study of leaf-related traits in tea plant in Guizhou based on genotyping-by-sequencing. BMC Plant Biology 23:196

    doi: 10.1186/s12870-023-04192-0

    CrossRef   Google Scholar

    [13]

    Ahmar S, Ballesta P, Ali M, Mora-Poblete F. 2021. Achievements and challenges of genomics-assisted breeding in forest trees: from marker-assisted selection to genome editing. International Journal of Molecular Sciences 22:10583

    doi: 10.3390/ijms221910583

    CrossRef   Google Scholar

    [14]

    Visscher PM, Wray NR, Zhang Q, Sklar P, McCarthy MI, et al. 2017. 10 years of GWAS discovery: biology, function, and translation. American Journal of Human Genetics 101:5−22

    doi: 10.1016/j.ajhg.2017.06.005

    CrossRef   Google Scholar

    [15]

    Fernandes SB, Casstevens TM, Bradbury PJ, Lipka AE. 2022. A multi-trait multi-locus stepwise approach for conducting GWAS on correlated traits. The Plant Genome 15:e20200

    doi: 10.1002/tpg2.20200

    CrossRef   Google Scholar

    [16]

    Visscher PM, Hemani G, Vinkhuyzen AAE, Chen GB, Lee SH, et al. 2014. Statistical power to detect genetic (co)variance of complex traits using SNP data in unrelated samples. PLoS Genetics 10:e1004269

    doi: 10.1371/journal.pgen.1004269

    CrossRef   Google Scholar

    [17]

    Speed D, Cai N, Johnson MR, Nejentsev S, Balding DJ, et al. 2017. Reevaluation of SNP heritability in complex human traits. Nature Genetics 49:986−92

    doi: 10.1038/ng.3865

    CrossRef   Google Scholar

    [18]

    Alamin M, Sultana MH, Lou X, Jin W, Xu H. 2022. Dissecting complex traits using omics data: a review on the linear mixed models and their application in GWAS. Plants 11:3277

    doi: 10.3390/plants11233277

    CrossRef   Google Scholar

    [19]

    Zhou X, Stephens M. 2014. Efficient multivariate linear mixed model algorithms for genome-wide association studies. Nature Methods 11:407−9

    doi: 10.1038/nmeth.2848

    CrossRef   Google Scholar

    [20]

    Korte A, Vilhjálmsson BJ, Segura V, Platt A, Long Q, et al. 2012. A mixed-model approach for genome-wide association studies of correlated traits in structured populations. Nature Genetics 44:1066−71

    doi: 10.1038/ng.2376

    CrossRef   Google Scholar

    [21]

    Pritikin JN, Neale MC, Prom-Wormley EC, Clark SL, Verhulst B. 2021. GW-SEM 2.0: efficient, flexible, and accessible multivariate GWAS. Behavior Genetics 51:343−57

    doi: 10.1007/s10519-021-10043-1

    CrossRef   Google Scholar

    [22]

    Yang W, Yao D, Wu H, Zhao W, Chen Y, et al. 2021. Multivariate genome-wide association study of leaf shape in a Populus deltoides and P. simonii F1 pedigree. PLoS ONE 16:e0259278

    doi: 10.1371/journal.pone.0259278

    CrossRef   Google Scholar

    [23]

    De La Torre AR, Sekhwal MK, Puiu D, Salzberg SL, Scott AD, et al. 2022. Genome-wide association identifies candidate genes for drought tolerance in coast redwood and giant sequoia. The Plant Journal 109:7−22

    doi: 10.1111/tpj.15592

    CrossRef   Google Scholar

    [24]

    Xia H, Hao Z, Shen Y, Tu Z, Yang L, et al. 2023. Genome-wide association study of multiyear dynamic growth traits in hybrid Liriodendron identifies robust genetic loci associated with growth trajectories. The Plant Journal 115:1544−63

    doi: 10.1111/tpj.16337

    CrossRef   Google Scholar

    [25]

    Stephens M. 2013. A unified framework for association analysis with multiple related phenotypes. PLoS ONE 8:e65245

    doi: 10.1371/journal.pone.0065245

    CrossRef   Google Scholar

    [26]

    Liu M, Zhao Y, Liu X, Korpelainen H, Li C. 2022. Ammonium and nitrate affect sexually different responses to salt stress in Populus cathayana. Physiologia Plantarum 174:e13626

    doi: 10.1111/ppl.13626

    CrossRef   Google Scholar

    [27]

    Zong D, Zhou A, Zhang Y, Zou X, Li D, et al. 2019. Characterization of the complete chloroplast genomes of five Populus species from the western Sichuan plateau, southwest China: comparative and phylogenetic analyses. PeerJ 7:e6386

    doi: 10.7717/peerj.6386

    CrossRef   Google Scholar

    [28]

    Cao D, Zhang Y, Cheng X, Xiang X, Zhang L, et al. 2021. Genetic variation of leaf phenotypic traits in different populations of Populus cathayana. Scientia Silvae Sinicae 57:56−67

    doi: 10.11707/j.1001-7488.20210806

    CrossRef   Google Scholar

    [29]

    Cheng X, Jia H, Sun P, Zhang Y, Hu J. 2019. Genetic variation analysis of leaf morphological traits in Populus deltoides cl. 'Danhong' × P. simonii cl. 'Tongliao 1' Hybrid Progenies. Forest Research 32:100−10

    doi: 10.13275/j.cnki.lykxyj.2019.02.015

    CrossRef   Google Scholar

    [30]

    Wickham H, François R, Henry L, Müller K, Vaughan D. 2023. dplyr: a grammar of data manipulation. R package version 1.1.4, https://dplyr.tidyverse.org.

    [31]

    Bates D, Mächler M, Bolker B, Walker S. 2015. Fitting linear mixed-effects models using lme4. Journal of Statistical Software 67:1−48

    doi: 10.18637/jss.v067.i01

    CrossRef   Google Scholar

    [32]

    Lê S, Josse J, Husson F. 2008. FactoMineR: an R package for multivariate analysis. Journal of Statistical Software 25:1−18

    doi: 10.18637/jss.v025.i01

    CrossRef   Google Scholar

    [33]

    Yu G, Smith DK, Zhu H, Guan Y, Lam TTY. 2017. ggtree: an r package for visualization and annotation of phylogenetic trees with their covariates and other associated data. Methods in Ecology and Evolution 8:28−36

    doi: 10.1111/2041-210X.12628

    CrossRef   Google Scholar

    [34]

    Xiang X, Zhou X, Zi H, Wei H, Cao D, et al. 2024. Populus cathayana genome and population resequencing provide insights into its evolution and adaptation. Horticulture Research 11:uhad255

    doi: 10.1093/hr/uhad255

    CrossRef   Google Scholar

    [35]

    Li H. 2013. Aligning sequence reads, clone sequences and assembly contigs with BWA-MEM. arXiv1303.3997

    doi: 10.48550/arXiv.1303.3997

    CrossRef   Google Scholar

    [36]

    Li H, Handsaker B, Wysoker A, Fennell T, Ruan J, et al. 2009. The Sequence Alignment/Map format and SAMtools. Bioinformatics 25:2078−79

    doi: 10.1093/bioinformatics/btp352

    CrossRef   Google Scholar

    [37]

    Mckenna A, Hanna M, Banks E, Sivachenko A, Cibulskis K, et al. 2010. The Genome Analysis Toolkit: a mapReduce framework for analyzing next-generation DNA sequencing data. Genome Research 20:1297−303

    doi: 10.1101/gr.107524.110

    CrossRef   Google Scholar

    [38]

    Danecek P, Auton A, Abecasis G, Albers CA, Banks E, et al. 2011. The variant call format and VCFtools. Bioinformatics 27:2156−58

    doi: 10.1093/bioinformatics/btr330

    CrossRef   Google Scholar

    [39]

    Chen H, Patterson N, Reich D. 2010. Population differentiation as a test for selective sweeps. Genome Research 20:393−402

    doi: 10.1101/gr.100545.109

    CrossRef   Google Scholar

    [40]

    San L, He Z, Liu Y, Zhang Y, Cao W, et al. 2023. Genetic diversity and signatures of selection in the Roughskin Sculpin (Trachidermus fasciatus) revealed by whole genome sequencing. Biology 12:1427

    doi: 10.3390/biology12111427

    CrossRef   Google Scholar

    [41]

    Purcell S, Neale B, Todd-Brown K, Thomas L, Ferreira MAR, et al. 2007. PLINK: a tool set for whole-genome association and population-based linkage analyses. American Journal of Human Genetics 81:559−75

    doi: 10.1086/519795

    CrossRef   Google Scholar

    [42]

    Zhou X, Stephens M. 2012. Genome-wide efficient mixed-model analysis for association studies. Nature Genetics 44:821−24

    doi: 10.1038/ng.2310

    CrossRef   Google Scholar

    [43]

    Nicotra AB, Leigh A, Boyce CK, Jones CS, Niklas KJ, et al. 2011. The evolution and functional significance of leaf shape in the angiosperms. Functional Plant Biology 38:535−52

    doi: 10.1071/FP11057

    CrossRef   Google Scholar

    [44]

    Yin L, Zhang H, Tang Z, Xu J, Yin D, et al. 2021. rMVP: a memory-efficient, visualization-enhanced, and parallel-accelerated tool for genome-wide association study. Genomics, Proteomics & Bioinformatics 19:619−28

    doi: 10.1016/j.gpb.2020.10.007

    CrossRef   Google Scholar

    [45]

    Shim H, Chasman DI, Smith JD, Mora S, Ridker PM, et al. 2015. A multivariate genome-wide association analysis of 10 LDL subfractions, and their response to statin treatment, in 1868 Caucasians. PLoS ONE 10:e0120758

    doi: 10.1371/journal.pone.0120758

    CrossRef   Google Scholar

    [46]

    Shannon P, Markiel A, Ozier O, Baliga NS, Wang JT, et al. 2003. Cytoscape: a software environment for integrated models of biomolecular interaction networks. Genome Research 13:2498−504

    doi: 10.1101/gr.1239303

    CrossRef   Google Scholar

    [47]

    McKown AD, Guy RD, Quamme L, Klápště J, La Mantia J, et al. 2014. Association genetics, geography and ecophysiology link stomatal patterning in Populus trichocarpa with carbon gain and disease resistance trade-offs. Molecular Ecology 23:5771−90

    doi: 10.1111/mec.12969

    CrossRef   Google Scholar

    [48]

    Zhu X, Sun F, Sang M, Ye M, Bo W, et al. 2022. Genetic architecture of heterophylly: single and multi-leaf genome-wide association mapping in Populus euphratica. Frontiers in Plant Science 13:870876

    doi: 10.3389/fpls.2022.870876

    CrossRef   Google Scholar

    [49]

    Holliday JA, Zhou L, Bawa R, Zhang M, Oubida RW. 2016. Evidence for extensive parallelism but divergent genomic architecture of adaptation along altitudinal and latitudinal gradients in Populus trichocarpa. New Phytologist 209:1240−51

    doi: 10.1111/nph.13643

    CrossRef   Google Scholar

    [50]

    Momayyezi M, Guy RD. 2017. Substantial role for carbonic anhydrase in latitudinal variation in mesophyll conductance of Populus trichocarpa Torr. & Gray. Plant, Cell & Environment 40:138−49

    doi: 10.1111/pce.12851

    CrossRef   Google Scholar

    [51]

    Ye M, Zhu X, Gao P, Jiang L, Wu R. 2020. Identification of quantitative trait loci for altitude adaptation of tree leaf shape with Populus szechuanica in the Qinghai-Tibetan plateau. Frontiers in Plant Science 11:632

    doi: 10.3389/fpls.2020.00632

    CrossRef   Google Scholar

    [52]

    Boyle EA, Li YI, Pritchard JK. 2017. An expanded view of complex traits: from polygenic to omnigenic. Cell 169:1177−86

    doi: 10.1016/j.cell.2017.05.038

    CrossRef   Google Scholar

    [53]

    Guo M, Zhang Z, Cheng Y, Li S, Shao P, et al. 2020. Comparative population genomics dissects the genetic basis of seven domestication traits in jujube. Horticulture Research 7:89

    doi: 10.1038/s41438-020-0312-6

    CrossRef   Google Scholar

    [54]

    Li L, Zhang C, Huang J, Liu Q, Wei H, et al. 2021. Genomic analyses reveal the genetic basis of early maturity and identification of loci and candidate genes in upland cotton (Gossypium hirsutum L.). Plant Biotechnology Journal 19:109−23

    doi: 10.1111/pbi.13446

    CrossRef   Google Scholar

    [55]

    Liu T, Wang P, Tian J, Guo J, Zhu W, et al. 2022. Polystyrene sulfonate is effective for enhancing biomass enzymatic saccharification under green liquor pretreatment in bioenergy poplar. Biotechnology for Biofuels and Bioproducts 15:10

    doi: 10.1186/s13068-022-02108-y

    CrossRef   Google Scholar

    [56]

    Wang J, Hu Z, Liao X, Wang Z, Li W, et al. 2022. Whole-genome resequencing reveals signature of local adaptation and divergence in wild soybean. Evolutionary Applications 15:1820−33

    doi: 10.1111/eva.13480

    CrossRef   Google Scholar

    [57]

    Hu Y, Feng C, Yang L, Edger PP, Kang M. 2022. Genomic population structure and local adaptation of the wild strawberry Fragaria nilgerrensis. Horticulture Research 9:uhab059

    doi: 10.1093/hr/uhab059

    CrossRef   Google Scholar

    [58]

    Rowland E, Kim J, Friso G, Poliakov A, Ponnala L, et al. 2022. The CLP and PREP protease systems coordinate maturation and degradation of the chloroplast proteome in Arabidopsis thaliana. New Phytologist 236:1339−57

    doi: 10.1111/nph.18426

    CrossRef   Google Scholar

    [59]

    Fukushima EO, Seki H, Ohyama K, Ono E, Umemoto N, et al. 2011. CYP716A subfamily members are multifunctional oxidases in triterpenoid biosynthesis. Plant and Cell Physiology 52:2050−61

    doi: 10.1093/pcp/pcr146

    CrossRef   Google Scholar

  • Cite this article

    Zhou X, Xiang X, Cao D, Zhang L, Hu J. 2024. Selective sweep and GWAS provide insights into adaptive variation of Populus cathayana leaves. Forestry Research 4: e012 doi: 10.48130/forres-0024-0009
    Zhou X, Xiang X, Cao D, Zhang L, Hu J. 2024. Selective sweep and GWAS provide insights into adaptive variation of Populus cathayana leaves. Forestry Research 4: e012 doi: 10.48130/forres-0024-0009

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ARTICLE   Open Access    

Selective sweep and GWAS provide insights into adaptive variation of Populus cathayana leaves

Forestry Research  4 Article number: e012  (2024)  |  Cite this article

Abstract: Leaf morphology plays a crucial role in predicting the productivity and environmental adaptability of forest trees, making it essential to understand the genetic mechanisms behind leaf variation. In natural populations of Populus cathayana, leaf morphology exhibits rich intraspecific variation due to long-term selection. However, there have been no studies that systematically reveal the genetic mechanisms of leaf variation in P. cathayana. To fill this gap and enhance our understanding of leaf variation in P. cathayana, we collected nine leaf traits from the P. cathayana natural population, consisting of 416 accessions, and conducted the preliminary classification of leaf types with four categories. Subsequently, we conducted an analysis of selective sweep and genome-wide association studies (GWAS) to uncover the genetic basis of leaf traits variation. Most of the leaf traits displayed significant correlations, with broad-sense trait heritability ranging from 0.38 to 0.74. In total, three selective sweep methods ultimately identified 278 positively selected candidate regions and 493 genes associated with leaf size. Single-trait and multi-trait GWAS methods detected 13 and 59 genes, respectively. By integrating the results of selective sweep and GWAS, we further identified a total of nine overlapping genes. These genes may play a role in the leaf development process and are closely associated with leaf size. In particular, the gene CBSCBSPB3 (Pca07G009100) located on chromosome 7, was associated with the response to light stimulation. This study will deepen our understanding of the genetic mechanism of leaf adaptive variation in P. cathayana and provide valuable gene resources.

    • Leaf morphology plays a pivotal role throughout various stages of plant growth and development, influencing crucial processes such as gas exchange and transpiration[1]. Moreover, it serves as a significant indicator for plant identification and a predictive marker for productivity, being directly and quantifiably influenced by environmental changes[2], and it also displays a wealth of variations. These variations are closely related to genetic variation and environmental factors. Understanding the genetic architecture and adaptive mechanisms of leaf variation has important ecological and evolutionary implications[3]. Currently, our understanding of the leaf trait variation in forest trees still requires further research.

      Common garden experiments are the most common approach used to study the genetic variation of traits in forest tree populations. Typically, these studies combine phenotypes and genomic variation to dissect genetic diversity[36]. Compared to other tree species, poplars exhibit rapid growth, are easy to propagate asexually, and have a relatively mature genetic transformation system[7]. Therefore, poplars are generally considered as model species for forest tree research[8]. Previous studies have identified several quantitative trait loci (QTLs) and single nucleotide polymorphisms (SNPs) associated with morphological traits of poplar leaves[4,8,9]. On this basis, a series of studies have been conducted on leaf variation in tree species such as Coffea mauritiana[10], Ginkgo biloba[11], and Camellia sinensis[12]. These studies have provided preliminary explorations into the genetic basis of leaf trait variation and identified candidate genes associated with leaf color, morphology, and thickness. They provide initial insights into the variation of leaf traits in forest trees controlled by multiple genes, but further exploration is still required.

      With advances in molecular biology, association genetics has emerged as a powerful tool for identifying the loci or genes underlying traits of interest. Among them, genome-wide association studies (GWAS) have been particularly prominent, playing an important role in understanding the genetic basis of plant traits[13]. Despite the high heritability of many morphological traits in forest trees, the significant SNPs associated with them only explain a small proportion of the heritability[14,15]. Complex traits often exhibit polygenicity, and traditional GWAS often struggle to detect the effects of alleles with small effect and low frequency[16,17]. Multi-trait GWAS overcomes this problem to some extent, using the correlations among traits and the combined weak genetic effects across traits to enhances GWAS statistical power and the ability to detect novel SNP loci[15,18]. Currently, the commonly used models for multi-trait GWAS are mainly the multivariate linear mixed model (mvLMM) and multi-trait mixed model (MTMM)[1921]. Among these, the mvLMM model runs faster than the MTMM and has higher accuracy for groups with smaller sample sizes[19], making it more suitable for forest tree studies. So far, it has been widely used in several tree species such as Populus trichocarpa[4,8], Populus deltoides[22], and Sequoiadendron giganteum[23]. Among them, Chhetri et al.[4] identified four and 20 candidate genes using single-trait and multi-trait GWAS, respectively, in their study of leaf traits in P. trichocarpa; Xia et al.[24] detected five and 114 significant associations using single-trait and multi-trait GWAS, respectively, in their research on growth traits of perennial hybrid Liriodendron. Indeed, multi-trait analyses can increase power not only to detect pleiotropic genetic variants, but also genetic variants that affect only one of multiple correlated phenotypes[25]. Multi-trait and single-trait GWAS should be viewed as complementary rather than competitive[19], and their integration will be beneficial for GWAS mining.

      Populus cathayana is a native species in China with rapid growth and ability to adapt to various complex environments[26,27]. The leaf morphology of P. cathayana population has shown a rich genetic variation. Here, we first conducted a study on the whole-genome variation of P. cathayana leaves traits. Based on the phenotypic data from a common garden experiment, we performed selective sweep and GWAS analysis to detect the genetic basis of leaf variation in P. cathayana. The aim is to deepen our understanding of leaf adaptive evolution and identify potential candidate genes. These findings will provide preliminary insights for the adaptive variation of forest leaves, and valuable genetic resources for poplar improvement.

    • The Populus cathayana Rehder (Salicaceae, Tacamahaca) association population consists of 416 genotypes, collected from 34 natural distribution areas in China[28], spaced at least 100 m from each other. All genotypes were propagated through vegetative reproduction by cuttings in the greenhouse of the Chinese Academy of Forestry. After two months of growth, they were transplanted to a common garden in Beijing, with 10−20 seedlings per genotype. The seedlings were spaced at 30 cm × 50 cm, and uniform water and fertilizer management was implemented.

    • In the spring of 2018, all P. cathayana genotypes were pruned at a height of 3 cm above the ground. In mid-July of the same year, three healthy and insect-free saplings were selected from each genotype, and fully expanded leaves from the 7th, 8th, and 9th positions counting from the top were collected to measure leaf chlorophyll content and morphological indices. The relative chlorophyll content (SPAD) of the leaves was determined using a hand-held Soil and Plant Analyzer Development chlorophyll meter, and the leaves were scanned and imaged using a scanner. After that, the leaf area (LA), leaf perimeter (LP), leaf length (LL), leaf width (LW) and petiole length (PL) were measured using Digimizer image processing software. Three compound leaf morphology traits were calculated according to the method described by Cheng et al.[29].

      $ Leaf\;index\left(LI\right) =Leaf\;length/Leaf\;width $
      $ Relative\;petiole\;length\left(RPL\right) =Petiole\;length/Leaf\;length $
      $ Leaf\;margin\;factor\left(LMF\right) = 4*Leaf\;area/{Leaf\;perimeter}^{2} $
    • All measurements were checked for recording errors, and outliers were removed. Phenotypic descriptive statistics (Supplemental Table S1) were calculated using dplyr v.1.1.2[30]. The variance components were estimated by applying a mixed linear model using lme4 v.1.1.34[31], with genotype as a random factor and replication as a fixed factor. The generalized heritability (H2) was calculated using the formula H2 = Vg/(Vg + Ve), where Vg and Ve represent the genetic and residual variance components, respectively. Additionally, based on the statistical results of leaf traits, we performed PCA analysis using FactoMineR v1.34[32], and conducted hierarchical clustering analysis using ggtree v.3.4.4[33].

    • Preparation of the genotypic data was as described in Xiang et al.[34]. Briefly, paired-end libraries were prepared according to Illumina's standard, and the P. cathayana association population was subjected to whole-genome resequencing using the Illumina HiSeq 2500 platform. Each sample was sequenced to a depth of approximately 30 X. After filtering the raw reads, the high-quality paired-end sequencing reads were aligned to the reference genome of P. cathayana (https://ngdc.cncb.ac.cn/?lang=en, PRJCA014016) using the BWA-MEM algorithm from the BWA v.0.7.8[35]. Subsequently, PCR amplified repeats were removed using SAMtools v.0.1.19[36], and SNP detection was performed using Genome Analysis Toolkit (GATK) v.4.0.4.0[37]. Finally, SNPs with an average sequencing depth < 20, quality < 30, minor allele frequency < 0.05, and missing genotype > 0.05 were filtered out using VCFtools v.0.1.16[38].

    • Selective sweep helps to identify genomic information associated with adaptive variations. Here, we used three methods for selective sweep analysis. Genetic differentiation coefficient (Fst) and nucleotide diversity (π) were calculated using the sliding window method with VCFtools v.0.1.16. XP-CLR was performed using the python version of XP-CLR v.1.1.2[39] with the parameters: --ld 0.95 -maxsnps 600 --size 10 kb --step 1 kb. Referring to the studies by Li et al.[3] & San et al.[40], we similarly used the top 5% window as the candidate region for selective scanning analysis. The overlapping regions among the three methods were defined as the final candidate regions for selective sweep. Then, the genes within final candidate regions were defined as selective sweep candidate genes, and enrichment analysis was performed on these selective sweep candidate genes using the GO (Gene Ontology) and KEGG (Kyoto Encyclopedia of Genes and Genomes) databases.

    • To further identify genes that play a key role in the variation of P. cathayana leaf traits, we conducted GWAS analysis. We first filtered out SNPs with a minor allele frequency > 0.05 and a missing genotype rate < 0.05 using VCFtools v.0.1.16[38]. Subsequently, we used Plink v1.90[41] (window size 50, step size 50, r2 ≥ 0.20) to filter out SNPs with a high degree of linkage disequilibrium to ensure the independence of the SNPs. Ultimately, 587,765 SNPs were retained for association analysis. We first conducted single-trait GWAS (Supplemental Table S2) using univariate linear mixed model (LMM) in GEMMA v.0.98.3[42]. In order to eliminate false positives in association analysis, the first three principal components (Supplemental Table S3) were used as a fixed effect, while kinship matrix (Supplemental Table S4) was used as a random effect. Principal component analysis (PCA) was performed using GCTA v1.93.2. Kinship matrix was also constructed using GEMMA v.0.98.3. The GWAS model was:

      $ \mathrm{y}=\mathrm{W}\mathrm{\alpha }+\mathrm{x}\beta +\mathrm{u}+\mathrm{e}, $

      where y is a vector of quantitative traits for n individuals, W is an n × c matrix of covariates (fixed effects), α is a vector of corresponding coefficients including the intercept, x is an n-vector of marker genotypes, β is the effect size of the marker, u is an n-vector of random effects, and e is an n-vector of errors[42].

    • Multi-trait GWAS enhances the signal strength of SNPs to some extent, and the degree of enhancement is closely associated with the correlation and functional relationships between traits. Here, we constructed five trait combinations (Supplemental Table S5) and employed the multivariate linear mixed model (mvLMM) in the GEMMA v0.98.3 to perform multi-trait GWAS. For example, based on inter-trait correlations, we combined four closely correlated leaf morphological traits (leaf area, leaf circumference, leaf length, and leaf width) as the main structural units of leaves. Considering the functional relationships among traits, we combined leaf area, SPAD and petiole length[4] as they may have potential effects on leaf photosynthesis. Considering the impact of leaf index and leaf margin factor on understanding leaf morphological traits and their implications for plant adaptability[43], we constructed two trait combinations based on the sub-traits of these two composite traits. In addition, we combined the three composite traits (relative petiole length, leaf index and leaf margin factor) as the overall evaluation of leaf traits. The multi-trait GWAS model was:

      $ \mathrm{Y}=\mathrm{W}\mathrm{A}+\mathrm{x}{\beta }^{d}+\mathrm{U}+\mathrm{E}, $

      where Y is an n by d matrix of quantitative traits for n individuals, W is an n × c matrix of covariates (fixed effects), A is c by d matrix of corresponding coefficients including the intercept, x is an n-vector of marker genotypes, βd is a d vector of marker effect sizes for the d phenotypes, U is an n by d matrix of random effects, and E an n by d matrix of errors[42].

    • CMplot v4.3.1 was used to generate Q-Q plot to assess the accuracy of the model and create Manhattan plots to visualize the GWAS results[44]. We used a p_value cutoff based on the Bonferroni correction criterion of 8.51 × 10−8 (0.05/n, where n is the effective number of SNPs) to identify significant associations for single-trait and multi-trait GWAS. Additionally, for single-trait GWAS, we also used a more liberal p_value cutoff of 1.70 × 10−6 (1/n, where n is the effective number of SNPs) to identify suggestive associations. For significant associations, we used the reference genome of P. cathayana as a reference and considered their upstream and downstream regions of 20 kb as candidate intervals to obtain GWAS candidate genes. Percentage of variance explained (PVE) by SNPs was estimated using the formula described by Shim et al.[45]. Since multi-trait output does not provide SE for effect size, the estimation of PVE for SNPs was not conducted. The PVE calculation formula was:

      $ PVE =\dfrac{{2\beta }^{2}{MAF(1-MAF)}}{{2\beta }^{2}{MAF(1-MAF)+}{\left(se\right(\beta \left)\right)}^{2}{2}{NMAF(1-MAF)}} $

      where, β = effect size, MAF = minor allele frequency, N = sample size, se(β) = SE of β.

    • Based on the gene annotation information of the P. cathayana genome, we used the GO and KEGG databases to predict the potential biological functions of candidate genes. To further screen candidate genes, we constructed a candidate gene network using Cytoscape v3.7.1[46]. Nodes denote traits and genes and node size denotes connectivity.

    • The distribution of leaf traits and correlations analysis between traits are shown in Fig. 1. Most leaf traits were significantly different (p < 0.01) within the P. cathayana population. The same results were also found between different source regions[28]. The five leaf morphological traits were significantly positively correlated among each other, and significantly negatively correlated with two composite traits (LI and LMF) as well as SPAD (Fig. 1). Broad-sense heritabilities ranged from 0.3791 to 0.7375 for leaf traits, with the highest being LMF and the lowest being SPAD coefficient of variation (Table 1).

      Figure 1. 

      Relationships between leaf traits. Scatter plots and histograms display the distribution of each trait. The red line overlaid on each histogram represents the density distribution. '*', '**' and '***' denote significant correlations at the 0.05, 0.01, and 0.001 levels, respectively. Red and blue asterisks represent positive and negative correlations, respectively.

      Table 1.  Results of statistical analysis of leaf traits.

      TraitAbbreviationMeanSDMinMaxCVaVgbVecH2d
      Leaf areaLA118.27237.23521.034219.5870.311,143.7214685.74880.6252
      Leaf perimeterLP51.9869.64223.01783.7620.1987.911166.33780.5699
      Leaf lengthLL16.3442.5117.73322.3270.155.43032.70190.6678
      Leaf widthLW10.2422.0723.48315.6330.203.92902.91500.5741
      Petiole lengthPL3.2051.0470.7865.5130.330.98760.38140.7214
      Relative petiole lengthRPL0.1970.0610.0660.3760.310.06710.02560.7234
      Leaf indexLI1.6450.2721.0422.5200.170.00030.00050.3791
      Leaf margin factorLMF0.1730.0190.1230.2320.110.00330.00120.7375
      Leaf chlorophyllSPAD41.9894.58730.99357.2330.117.07704.96800.5875
      a Coefficient of variation; b genetic variance; c residual variance; d heritability,
    • We performed principal components analysis (PCA) to further explore the relationships among traits within the P. cathayana population. PC1 explained over 54% of the total variation, with PC1 and PC2 together explaining 80% of the total variation. Five morphological traits were negatively weighted towards the PC1 axis, while SPAD was positively weighted towards that axis. RPL and LMF were positively weighted towards the PC2 axis, while LI was negatively weighted towards that axis (Fig. 2a). Furthermore, through the clustering analysis, we have classified the P. cathayana leaves into four categories: long-stalked large leaf (LSLL), long-stalked medium leaf (LSML), short-stalked medium leaf (SSML), and short-stalked small leaf (SSSL) (Fig. 2b, c, Supplemental Table S6).

      Figure 2. 

      Principal component analysis (PCA) and hierarchical clustering analysis based on leaf phenotype data. (a) The PCA plot showing the first and second principal components of P. cathayana genotypes, represented by color-coded points, and the relative importance of explanatory variables is indicated by vectors. (b) Clustering of P. cathayana populations into four categories based on leaf traits. (c) Comparison of four leaf shape categories[28].

    • In our previous study, we considered the P. cathayana population to be divided into four groups: NW (Northwest China), SW (Southwest China), TH (Tai-hang Mountains), and NC (North China) (Supplemental Fig. S1). We observed that LSLL genotypes were predominantly concentrated in the NW group, while SSSL genotypes were mainly found in the TH group. To identify selected genes associated with leaf size during leaf variation, we selected 10 LSLL genotypes from the TH group and 10 SSSL genotypes from the NW group for selective sweep analysis. Fst, π, and XP-CLR identified a total of 278 overlapping regions (Fig. 3). Further, 493 selective sweep candidate genes were identified (Supplemental Table S7). These candidate genes were significantly enriched in GO terms closely related to leaf development, including cell growth, cell death, auxin biosynthesis and metabolic processes, protein kinase activity, and aspects of the photosynthetic membrane such as chloroplast thylakoids (Fig. 4a, Supplemental Table S8). In addition, these genes were notably enriched in several metabolic pathways, including plant-pathogen interaction, photosynthesis, starch and sucrose metabolism, and biosynthesis of unsaturated fatty acids. Overall, enrichment analysis preliminarily suggests that the candidate genes play significant roles in leaf development (Fig. 4b, Supplemental Table S9).

      Figure 3. 

      Selective sweep analysis visual line chart and frequency histogram. Genetic differentiation coefficient (Fst) and nucleotide diversity (π) were calculated by the sliding window method with a window size of 10 kb and a step size of 1 kb; XP-CLR has the same window size as Fst and π. The plots (a), (b) and (c) respectively represent the line graph and frequency histogram of Fst, π, and XP-CLR. In the line plot, the blue line and red line represent the top 5% and top 1% thresholds, respectively, and correspond to the blue and red shaded areas in the frequency histogram. The interval that passes the top 5% threshold lines in three methods is considered as the final candidate region for selective sweep.

      Figure 4. 

      Functional enrichment analysis of selective sweep candidate genes. (a) GO enrichment analysis of candidate genes, where the size of the points represents the number of genes, and the color of the points indicates significance level. BP, CC, MF respectively represent biological process, cellular component, and molecular function. (b) KEGG enrichment analysis of candidate genes, where the size of the points represents the number of genes, and the color of the points indicates significance level.

    • GWAS was conducted to further identify candidate genes associated with leaf morphology. For single-trait GWAS, we identified a total of six significant SNPs across the nine leaf traits (Supplemental Figs S2 & 3). These SNPs were located within or near 13 gene, with explained PVE ranging from 1.08% to 3.34% (Table 2). For multi-traits GWAS, we identified a total of 33 significant SNPs associated with at least one of the five sets of traits (Fig. 5ae, Supplemental Fig. S4). These SNPs were located within or close to 59 gene (Supplemental Table S10). Ultimately, the two GWAS methods identified a total of 67 candidate genes associated with leaf traits; Among them, five candidate genes overlapped in the two GWAS methods (Supplemental Table S11). In addition, using a more liberal p_value cutoff of 1.70 × 10−6, we associated a total of 41 suggestive association SNPs in nine single-trait GWAS (Supplemental Fig. S2). These SNPs explained PVE ranging from 0.01% to 3.18%, and identifying 52 suggestive candidate genes (Supplemental Table S12). Among these suggestive candidate genes, eight overlapped with the candidate genes from the multi-trait GWAS. These overlapping genes are initially deemed key candidate genes likely to influence the leaf morphology of P. cathayana (Supplemental Table S13).

      Table 2.  Statistical information of significant SNPs in single-trait GWAS.

      rsaTraitp_valuePVEbGeneFunctional annotation
      19__8697977LW5.36E-083.15Pca19G006210Reverse transcriptase
      Pca19G006220RNase H-like domain found in reverse transcriptase
      10__3487289LL6.77E-082.97Pca10G001830Protein tyrosine and serine/threonine kinase
      Pca10G001840D-mannose binding lectin
      9__9068032PL1.04E-083.34Pca09G008070WD domain, G-beta repeat
      Pca09G008080Clp protease
      Pca09G008090C2H2-type zinc finger
      8__15332723SPAD2.24E-083.24Pca08G0188005' nucleotidase family
      1__26393650RPL2.10E-081.98Pca01G022670NA
      Pca01G022680Protein of unknown function (DUF1117)
      9__9068032RPL5.28E-082.20Pca09G008070WD domain, G-beta repeat
      Pca09G008080Clp protease
      Pca09G008090C2H2-type zinc finger
      18__14798104LMF4.57E-091.08Pca18G011690Cytochrome P450
      Pca18G011700Protein tyrosine and serine/threonine kinase
      Pca18G011710Cytochrome P450
      NA, not available. a The name of the SNP. b The proportion of phenotype variance explained by SNP.

      Figure 5. 

      GEMMA multi-trait GWAS Manhattan plots and significant locus analysis. The plots (a), (b), (c), (d), and (e) correspond to the manhattan plots of LA_LP_LL_LW, LA_PL_SPAD, LI_LW_LL, LMF_LA_LP and RPL_LI_LMF, respectively. For ease of comparison, we have included the single-trait GWAS Manhattan plots of the traits in the figures. Each dot on the plot represents a SNP, with dot colors indicate single-trait or multi-trait associations. p_value were transformed into −log10(p_value). SNPs above green lines passed bonferroni correction test (p ≤ 8.51 × 10−8). The red circle represents the detected loci in multiple trait combinations. (f) Analysis of genetic differentiation (Fst) and nucleotide diversity (π) near SNP 7__12437614. (g) Comparison of leaf phenotypes corresponding to three haplotypes at SNP 7__12437614, represented by mean values in a bar graph with standard deviation as the error. (h) Analysis of genetic differentiation (Fst) and nucleotide diversity (π) near SNP 18__14798104. (i) Comparison of leaf phenotypes between two haplotypes at SNP 18__14798104, represented by mean values in a bar graph with standard deviation as the error.

      To further clarify the biological functions of the GWAS candidate genes, we conducted enrichment analysis on the GWAS candidate genes (Supplemental Fig. S5a, b). The candidate genes were involved in various GO terms, including saponin and glycoside biosynthetic and metabolic process, phytosteroid biosynthetic process, response to abscisic acid, response to stimulus, chloroplastic endopeptidase clp complex, response to hormone (Supplemental Table S14). Moreover, they are associated with KEGG metabolic pathways such as protein processing in endoplasmic reticulum, cyanoamino acid metabolism, phenylpropanoid biosynthesis, starch and sucrose metabolism, flavonoid biosynthesis, plant hormone signal transduction (Supplemental Table S15). The results of the enrichment analysis provide preliminary evidence that the GWAS candidate genes play a role in regulating leaf traits, either directly or indirectly.

    • In multi-trait GWAS, there are two loci that show significant associations in different trait combinations, and they warrant further investigation. Among them, SNP 7__12437614 on chromosome 7 showed a close association with the LA trait (Fig. 5ac), and was located within Pca07G009100 (CBSCBSPB3). This gene contains the CBS domain, and GO enrichment analysis indicates its involvement in the response to light stimulus. SNP 18__14798104 on chromosome 18 showed a close association with the LMF trait (Fig. 5c, d) and was located within the coding region of Pca18G011700 (PIX13). This gene encodes the tyrosine and serine/threonine kinase proteins, and GO enrichment analysis indicates its involvement in defense responses and responses to external stimuli, as well as other GO processes; The neighboring genes Pca18G011690 (CYP716A17) and Pca18G011710 both encode Cytochrome P450, which may be involved in the synthesis of chlorophyll and other photosynthetic pigments. Fst and π analysis results indicated significant differentiation between the SHSL and LHLL categories near these two SNPs (Fig. 5f, h). This further suggests that these loci may play a key role in promoting genetic differentiation and adaptive phenotypic variation. Furthermore, the observed phenotypic differences between different haplotypes provide support for the involvement of these SNPs in trait variation (Fig. 5g, i). These results further suggest that candidate genes may regulate leaf development by affecting leaf photosynthetic capacity.

    • To further identify important candidate genes, we constructed a candidate gene network using Cytoscape v3.7.1 (Fig. 6, Supplemental Table S16). The number of overlapping GWAS candidate genes among different leaf traits was closely related to the correlation among traits, with no overlapping genes found between SPAD and other traits. Within the entire network, 18 GWAS candidate genes were associated with at least two leaf trait variations. The gene Pca09G008080 (CLPR1), encoding an ATP-dependent Clp protease proteolytic subunit-related protein, and the gene Pca10G001830, encoding protein tyrosine and serine/threonine kinase, showed high connectivity in the network. Selective sweep and GWAS identified a total of nine overlapping genes (Supplemental Table S17), and these genes may play a role in the leaf development process and are closely associated with leaf size. Among them, the gene CBSCBSPB3, associated with the response to light stimulation, was identified as a key candidate gene in GWAS analysis of this study.

      Figure 6. 

      Candidate gene network visualization. Circles represent candidate genes, and the size of the circles indicates the number of associated traits. The color of the circles corresponds to different types of candidate genes. Lines represent the traits associated with genes and whether they are candidate genes for selective sweep.

    • Leaf size and shape are crucial traits in the development and growth of poplar[9]. Identifying the genetic mechanisms underlying leaf trait variation holds profound implications for poplar breeding. For a long time, leaf trait research has been an important direction of forest tree research. However, our understanding of the gene regulatory networks and genetics underlying leaf development is still limited[22,47]. With advancements in biotechnology, the genomic era has provided possibilities for further studying the variations in leaf traits. Populus, as model forest tree species, has been subject to a series of GWAS studies on leaf traits, such as P. trichocarpa[4] and P. euphratica[48]. These studies indicated that leaf traits have exhibited abundant genetic variation within poplar populations. Our study similarly confirms the presence of rich leaf variation in P. cathayana, enabling the preliminary classification of P. cathayana leaves into four categories (LSLL, LSML, SSML and SSSL).

      Previous research has suggested that poplar leaf trait variations were primarily driven by geographical factors, with many leaf traits correlating with altitude and latitude[8,49]. P. cathayana leaf morphological traits exhibit high correlations among themselves and negative correlations with chlorophyll content (SPAD), which are consistent with previous studies. Furthermore, they also pointed out that the morphological characteristics of poplar leaves not only affect chlorophyll content but also influence leaf thickness and stomatal density, subsequently impacting poplar tree nitrogen content, stomatal conductance, and photosynthesis[50], ultimately affecting tree growth. Significant variation in leaf traits within P. cathayana populations may be closely associated with environmental factors such as temperature, precipitation, and solar radiation lamps, in addition to genetic factors.

      Previously, there have been no reports on whole-genome studies of leaf traits in P. cathayana. Here, we systematically carried out the first whole-genome study of P. cathayana leaves. We observed that the ability of GWAS to mine single traits was limited, and most traits were difficult to associate to specific genetic variant loci. This phenomenon is present not only for leaf traits but also for most traits of forest trees[3,4,8,9,22,48,51]. The reasons for this limitation have been discussed in previous studies[4,14,52]. One of the primary reasons is the relatively small population size used in forest tree association analyses, which makes it difficult to detect the effects of alleles with small effect sizes and low frequencies. Therefore, we considered applying multi-trait mixed linear model to improve the mining power in addition to the conventional GWAS analysis[4,19]. In our study, multi-trait GWAS identified more candidate genes than single-trait GWAS, and this increased power of multi-trait GWAS depends in part on the correlation among traits.

      Selective sweep and GWAS provide possibility for studying adaptive variations and have been widely used[5357]. Li et al.[3] used GWAS, selective sweep and multi-omics data to identify 41 representative genes potentially involved in stomatal morphological variation and photosynthetic capacity in P. tomentosa. In this study, several genes (CBSCBSPB3, CYP716A17, CLPR1) were identified through selective sweep and GWAS, which may be related to leaf function in Arabidopsis[58,59]. Their functional annotations in the P. cathayana genome are associated with light stimulation, photosynthesis, chloroplast development, and stress response. Therefore, we preliminarily consider them to be key candidate genes for exploring leaf variation in P. cathayana. Furthermore, by selective sweep we also identified multiple genes associated with cell development, photosynthesis, and chloroplasts.

      Compared to previously reported GWAS studies on poplar leaf traits[3,4,9,22,48,51], we found few overlapping genes across different studies. By studying the functions of these candidate genes, we found that candidate genes are functionally enriched in cell development, carbohydrate metabolism, plant-pathogen interactions, and flavonoid biosynthesis. In our study, GWAS candidate genes also displayed similar functions. Notably, we found that unlike other leaf GWAS studies, P. cathayana leaf traits GWAS candidate genes were significantly enriched in GOs such as response to abscisic acid and mitotic cell cycle. We believe that our study provides valuable insights into a portion of the genetic variation behind the phenotypic traits of leaves.

    • In summary, we have reported the first genome-wide study on leaf traits in P. cathayana and classified the leaf types of P. cathayana into four major categories. Integrating selective sweep and GWAS, we conducted a preliminary exploration of the genetic basis of leaf variation in P. cathayana. We detected candidate genes associated with photosynthesis and chloroplast development that may play a key role in leaf variation. Through single-trait and multi-trait GWAS analyses, we further identified candidate genes involved in regulating leaf morphology variation. Integrating selective sweep and GWAS result further identified the important role of CBSCBSPB3 in leaf phenotype variations. Our findings advance the understanding of adaptive variation of leaf traits and provided valuable genetic resources for improving the adaptations of forest tree.

    • The authors confirm contribution to the paper as follows: study design and draft the manuscript: Zhang L, Hu J; experimental materials and data collection: Xiang X, Cao D, Zhang L; interpretation of results: Xiang X, Zhang L; manuscript revision: Zhou X, Hu J. All authors reviewed the results and approved the final version of the manuscript.

    • The P. cathayana genome sequencing data have been deposited in National Genomics Data Center (https://ngdc.cncb.ac.cn/?lang=en), under BioProject PRJCA014016, with accession numbers SAMC1029101-SAMC1029104. The whole-genome resequencing data have been deposited under National Genomics Data Center BioProject PRJCA014017 with accession numbers SAMC1029105-SAMC1029542. All other data related to this study can be located in the supplementary files of the article.

      • This work was supported by the National Key Research and Development Program of China (2021YFD2200201), the Major Project of Agricultural Biological Breeding (2022ZD0401501) and the National Natural Science Foundation (32071797).

      • The authors declare that they have no conflict of interest.

      • # Authors contributed equally: Xinglu Zhou, Xiaodong Xiang

      • Supplemental Table S1 The statistical results of nine leaf traits of each P. cathayana genotype.
      • Supplemental Table S2 List of P. cathayana leaf traits and GWAS parameters.
      • Supplemental Table S3 The information of the first three principal components in the PCA analysis of the genotype data.
      • Supplemental Table S4 Genetic relationship matrix of genotypes in the P. cathayana population.
      • Supplemental Table S5 List of traits used for multitrait associations in P. cathayana.
      • Supplemental Table S6 Statistical information on leaf traits of four leaf categories.
      • Supplemental Table S7 Information on candidate genes identified by the three selective sweep methods.
      • Supplemental Table S8 GO enrichment analysis of selective sweep condidate genes.
      • Supplemental Table S9 KEGG enrichment analysis of selective sweep condidate genes.
      • Supplemental Table S10 Statistical information of significantly associated SNPs identified by multi-trait GWAS.
      • Supplemental Table S11 Annotation information of GWAS candidate genes.
      • Supplemental Table S12 Statistical results and PVE of suggestive association SNPs.
      • Supplemental Table S13 Annotation information of key candidate genes.
      • Supplemental Table S14 GO enrichment analysis of GWAS candidate genes.
      • Supplemental Table S15 KEGG enrichment analysis of GWAS candidate genes.
      • Supplemental Table S16 Candidate gene network visualization.
      • Supplemental Table S17 The functional annotation information of overlapping genes between selective sweep and GWAS.
      • Supplemental Fig. S1    Phylogenetic tree and population structure of P. cathayana populations[34]. Each individual is denoted by a vertical bar composed of different colors corresponding to its proportion of genetic ancestry.
      • Supplemental Fig. S2 Manhattan plots GEMMA single-trait GWAS in P. cathayana. P-values were transformed into log10 (p). Each dot represents a single nucleotide polymorphism (SNP), and SNPs above green lines passed bonferroni correction test (p ≤8.51 × 108), while SNPs above grey lines are considered suggestive associations (p ≤ 1.70 × 10−6).
      • Supplemental Fig. S3 QQ plot for single-trait GWAS analysis, corresponding to the manhattan plots for single-trait GWAS.
      • Supplemental Fig. S4 QQ plot for multi-trait GWAS analysis. The plots (a, b, c, d, and e) correspond to the QQ plots of LA_LP_LL_LW, LA_PL_SPAD, LI_LW_LL, LMF_LA_LP and RPL_LI_LMF, respectively.
      • Supplemental Fig. S5 Functional enrichment analysis of GWAS candidate genes. a: GO enrichment analysis of candidate genes, where the size of the points represents the number of genes, and the color of the points indicates significance level. BP, CC, MF respectively represent biological process, cellular component, and molecular function. b: KEGG enrichment analysis of candidate genes, where the size of the points represents the number of genes, and the color of the points indicates significance level.
      • Copyright: © 2024 by the author(s). Published by Maximum Academic Press, Fayetteville, GA. This article is an open access article distributed under Creative Commons Attribution License (CC BY 4.0), visit https://creativecommons.org/licenses/by/4.0/.
    Figure (6)  Table (2) References (59)
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    Zhou X, Xiang X, Cao D, Zhang L, Hu J. 2024. Selective sweep and GWAS provide insights into adaptive variation of Populus cathayana leaves. Forestry Research 4: e012 doi: 10.48130/forres-0024-0009
    Zhou X, Xiang X, Cao D, Zhang L, Hu J. 2024. Selective sweep and GWAS provide insights into adaptive variation of Populus cathayana leaves. Forestry Research 4: e012 doi: 10.48130/forres-0024-0009

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