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Home > Archive>Volume 22, Issue 1, 2021 >7-15. DOI:10.13430/j.cnki.jpgr.20200528001
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Research Progress on Pangenome and Its Application in Plant Functional Genetics
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Rice research institute, Guangdong Academic of Agricultural Sciences/Guangdong Key Laboratory of New Technology in Rice Breeding, Guangzhou 510640

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Guangdong Basic and Applied Basic Research Foundation( 2020A1515010906), Special Fund for Scientific Innovation Strategyconstruction of High Level Academy of Agriculture Science( R2019-JX001), Key Areas Research Projects of Guangdong Province( 2018B020202004), Team Project of Guangdong Agricultural Department( 2019KJ106), Scientific and Technological Plan of Guangzhou( 201804020078)

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    Abstract:

    The reference genome provides a fundamental framework in the field of modern functional genomics. Modern genomic techniques based on reference genomes is the driving force for identification of genetic variations and functional gene cloning in the past two decades. However, with the progress of plant genome research, it is becoming visible that single reference genome cannot represent all the genomic variances within a species or a population. This consequence has become one of the limits for the functional genomic studies. Pangenome refers to the full complement of genes/genomic sequences within a population. By capturing and presenting all the genes/genomic sequences within a population, pangenome can be used as reference genome in functional genetic studies, to overcome the limit posed by single reference genome. While implementing in the state-of-art genomic techniques, pangenome can greatly improve the efficiency and precision of identification of genetic variations in plant germplasm, thus becoming one of the frontiers and hotspots in genomic research. In this review, we summarized the definition and recent progress in studies of pangenome, the techniques and strategies applied in pangenome assembly and construction, as well as the application of pangenome in plant genomic and molecular breeding. The current problems and future perspectives of plant pangenome were outlined. This review is expected to provide a better understanding and reference for future study and application of plant pangenome.

    Reference
    [1] Wang W, Mauleon R, Hu Z, Chebotarov D, Tai S, Wu Z, Li M, Zheng T, Fuentes RR, Zhang F: Genomic variation in 3,010 diverse accessions of Asian cultivated rice. Nature, 2018, 557:43-49.
    [2] Tao Y, Zhao X, Mace E, Henry R, Jordan D: Exploring and exploiting pan-genomics for crop improvement. Molecular Plant 2019, 12:156-169.
    [3] Tranchant‐Dubreuil C, Rouard M, Sabot F: Plant Pangenome: Impacts on Phenotypes and Evolution. Annual Plant Reviews 2018:1-25.
    [4] 李娜, 尚建立, 周丹, 李楠楠, 王吉明, 马双武: 一个获得与缺失变异 (PAV) 调控甜瓜果实苦味. 植物遗传资源学报 2020, 21:377-385.Li N, Shang J L, Zhou D, Li N N, Wang J M, Ma S W, A Presence-absence Variation Regulates Fruit Bitterness in Melon (Cucumis melo L.). Journal of Plant Genetic Resources. 2020, 21(2): 377-385
    [5] Martinez-Murcia A, Benlloch S, Collins M: Phylogenetic interrelationships of members of the genera Aeromonas and Plesiomonas as determined by 16S ribosomal DNA sequencing: lack of congruence with results of DNA-DNA hybridizations. International Journal of systematic and evolutionary microbiology 1992, 42:412-421.
    [6] Tettelin H, Masignani V, Cieslewicz MJ, Donati C, Medini D, Ward NL, Angiuoli SV, Crabtree J, Jones AL, Durkin AS: Genome analysis of multiple pathogenic isolates of Streptococcus agalactiae: implications for the microbial “pan-genome”. Proceedings of the National Academy of Sciences 2005, 102:13950-13955.
    [7] Zhao J, Bayer PE, Ruperao P, Saxena RK, Khan AW, Golicz AA, Nguyen HT, Batley J, Edwards D, Varshney RK: Trait associations in the pangenome of pigeon pea (Cajanus cajan). Plant Biotechnology Journal 2020, n/a.
    [8] Song J-M, Guan Z, Hu J, Guo C, Yang Z, Wang S, Liu D, Wang B, Lu S, Zhou R: Eight high-quality genomes reveal pan-genome architecture and ecotype differentiation of Brassica napus. Nature Plants 2020:1-12.
    [9] Tian X, Li R, Fu W, Li Y, Wang X, Li M, Du D, Tang Q, Cai Y, Long Y: Building a sequence map of the pig pan-genome from multiple de novo assemblies and Hi-C data. Science China Life Sciences 2019:1-14.
    [10] Sherman RM, Forman J, Antonescu V, Puiu D, Daya M, Rafaels N, Boorgula MP, Chavan S, Vergara C, Ortega VE: Assembly of a pan-genome from deep sequencing of 910 humans of African descent. Nature Genetics 2019, 51:30-35.
    [11] Li Y-h, Zhou G, Ma J, Jiang W, Jin L-g, Zhang Z, Guo Y, Zhang J, Sui Y, Zheng L: De novo assembly of soybean wild relatives for pan-genome analysis of diversity and agronomic traits. Nature Biotechnology 2014, 32:1045.
    [12] Golicz AA, Bayer PE, Bhalla PL, Batley J, Edwards DJTiG: Pangenomics Comes of Age: From Bacteria to Plant and Animal Applications. 2019.
    [13] Carlos Guimaraes L, Benevides de Jesus L, Vinicius Canario Viana M, Silva A, Thiago Juca Ramos R, de Castro Soares S, Azevedo V: Inside the pan-genome-methods and software overview. Current genomics 2015, 16:245-252.
    [14] Vernikos G, Medini D, Riley DR, Tettelin H: Ten years of pan-genome analyses. Current opinion in microbiology 2015, 23:148-154.
    [15] Morgante M, De Paoli E, Radovic S: Transposable elements and the plant pan-genomes. Current opinion in plant biology 2007, 10:149-155.
    [16] Golicz AA, Bayer PE, Barker GC, Edger PP, Kim H, Martinez PA, Chan CKK, Severn-Ellis A, McCombie WR, Parkin IA: The pangenome of an agronomically important crop plant Brassica oleracea. Nature Communications 2016, 7:1-8.
    [17] Zhao Q, Feng Q, Lu H, Li Y, Wang A, Tian Q, Zhan Q, Lu Y, Zhang L, Huang T: Pan-genome analysis highlights the extent of genomic variation in cultivated and wild rice. Nature Genetics 2018, 50:278-284.
    [18] Jiao W-B, Schneeberger K: Chromosome-level assemblies of multiple Arabidopsis genomes reveal hotspots of rearrangements with altered evolutionary dynamics. Nature communications 2020, 11:1-10.
    [19] Gordon SP, Contreras-Moreira B, Woods DP, Des Marais DL, Burgess D, Shu S, Stritt C, Roulin AC, Schackwitz W, Tyler L: Extensive gene content variation in the Brachypodium distachyon pan-genome correlates with population structure. Nature communications 2017, 8:1-13.
    [20] Hurgobin B, Golicz AA, Bayer PE, Chan CKK, Tirnaz S, Dolatabadian A, Schiessl SV, Samans B, Montenegro JD, Parkin IA: Homoeologous exchange is a major cause of gene presence/absence variation in the amphidiploid Brassica napus. Plant biotechnology journal 2018, 16:1265-1274.
    [21] Lin K, Zhang N, Severing EI, Nijveen H, Cheng F, Visser RG, Wang X, de Ridder D, Bonnema G: Beyond genomic variation-comparison and functional annotation of three Brassica rapagenomes: a turnip, a rapid cycling and a Chinese cabbage. Bmc Genomics 2014, 15:250.
    [22] Ou L, Li D, Lv J, Chen W, Zhang Z, Li X, Yang B, Zhou S, Yang S, Li W: Pan-genome of cultivated pepper (Capsicum) and its use in gene presence-absence variation analyses. The New phytologist 2018, 220:360.
    [23] Hübner S, Bercovich N, Todesco M, Mandel JR, Odenheimer J, Ziegler E, Lee JS, Baute GJ, Owens GL, Grassa CJJNp: Sunflower pan-genome analysis shows that hybridization altered gene content and disease resistance. 2019, 5:54-62.
    [24] Zhou P, Silverstein KA, Ramaraj T, Guhlin J, Denny R, Liu J, Farmer AD, Steele KP, Stupar RM, Miller JR: Exploring structural variation and gene family architecture with De Novo assemblies of 15 Medicago genomes. BMC genomics 2017, 18:261.
    [25] Wang M, Yu Y, Haberer G, Marri PR, Fan C, Goicoechea JL, Zuccolo A, Song X, Kudrna D, Ammiraju JSJNg: The genome sequence of African rice (Oryza glaberrima) and evidence for independent domestication. 2014, 46:982-988.
    [26] Pinosio S, Giacomello S, Faivre-Rampant P, Taylor G, Jorge V, Le Paslier MC, Zaina G, Bastien C, Cattonaro F, Marroni F: Characterization of the poplar pan-genome by genome-wide identification of structural variation. Molecular biology and evolution 2016, 33:2706-2719.
    [27] Yu J, Golicz AA, Lu K, Dossa K, Zhang Y, Chen J, Wang L, You J, Fan D, Edwards D: Insight into the evolution and functional characteristics of the pan‐genome assembly from sesame landraces and modern cultivars. Plant biotechnology journal 2019, 17:881-892.
    [28] Gao L, Gonda I, Sun H, Ma Q, Bao K, Tieman DM, Burzynski-Chang EA, Fish TL, Stromberg KA, Sacks GL: The tomato pan-genome uncovers new genes and a rare allele regulating fruit flavor. Nature Genetics 2019, 51:1044-1051.
    [29] Montenegro JD, Golicz AA, Bayer PE, Hurgobin B, Lee H, Chan CKK, Visendi P, Lai K, Dole?el J, Batley J: The pangenome of hexaploid bread wheat. The Plant Journal 2017, 90:1007-1013.
    [30] Hirsch CN, Foerster JM, Johnson JM, Sekhon RS, Muttoni G, Vaillancourt B, Pe?agaricano F, Lindquist E, Pedraza MA, Barry K: Insights into the maize pan-genome and pan-transcriptome. The Plant Cell 2014, 26:121-135.
    [31] Danilevicz MF, Fernandez CGT, Marsh JI, Bayer PE, Edwards D: Plant pangenomics: approaches, applications and advancements. Current Opinion in Plant Biology 2020, 54:18-25.
    [32] Michael TP, VanBuren R: Building near-complete plant genomes. Current Opinion in Plant Biology 2020, 54:26-33.
    [33] Jiao W-B, Schneeberger K: The impact of third generation genomic technologies on plant genome assembly. Current Opinion in Plant Biology 2017, 36:64-70.
    [34] Song W-Y, Wang G-L, Chen L-L, Kim H-S, Pi L-Y, Holsten T, Gardner J, Wang B, Zhai W-X, Zhu L-H: A receptor kinase-like protein encoded by the rice disease resistance gene, Xa21. science 1995, 270:1804-1806.
    [35] Peter J, De Chiara M, Friedrich A, Yue J-X, Pflieger D, Bergstr?m A, Sigwalt A, Barre B, Freel K, Llored A: Genome evolution across 1,011 Saccharomyces cerevisiae isolates. Nature 2018, 556:339-344.
    [36] Xu K, Xu X, Fukao T, Canlas P, Maghirang-Rodriguez R, Heuer S, Ismail AM, Bailey-Serres J, Ronald PC, Mackill DJJN: Sub1A is an ethylene-response-factor-like gene that confers submergence tolerance to rice. 2006, 442:705-708.
    [37] Gage JL, Vaillancourt B, Hamilton JP, Manrique-Carpintero NC, Gustafson TJ, Barry K, Lipzen A, Tracy WF, Mikel MA, Kaeppler SM: Multiple maize Reference genomes impact the identification of variants by genome-wide association study in a diverse inbred panel. The Plant Genome 2019, 12.
    [38] Hurgobin B, Edwards D: SNP discovery using a pangenome: has the single Reference approach become obsolete? Biology 2017, 6:21.
    [39] Brody JA, Morrison AC, Bis JC, O'Connell JR, Brown MR, Huffman JE, Ames DC, Carroll A, Conomos MP, Gabriel S: Analysis commons, a team approach to discovery in a big-data environment for genetic epidemiology. Nature genetics 2017, 49:1560-1563.
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History
  • Received:May 28,2020
  • Revised:July 06,2020
  • Adopted:July 23,2020
  • Online: January 07,2021
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