User:DCDuring/List of sequenced plant genomes

This list of sequenced plant genomes contains plant species known to have publicly available complete genome sequences that have been assembled, annotated and published. Unassembled genomes are not included, nor are organelle only sequences. For all kingdoms, see the list of sequenced genomes.

Algae

Unicellular photosynthetic eukaryotes.

Organism strain	Clade	Relevance	Genome size	Number of genes predicted	Organization	Year of completion	Assembly status	Links
Cyanophora paradoxa	Glaucophyte				Rutgers University[1]	2012[1]
Bathycoccus prasinos BBAN7	Green algae	Comparative analysis	15 Mb		Joint Genome Institute	2012[2]
Chlamydomonas reinhardtii CC-503 cw92 mt+	Green algae	Model organism	111 Mb	17,737	University of California at Los Angeles[3]	2007		Template:NCBI taxid Template:ENA
Chlorella variabilis NC64A	Green algae					2010[4]
Coccomyxa subellipsoidea sp. C-169	Green algae	Model biofuel			Joint Genome Institute	2007[5]
Dunaliella salina CCAP19/18	Green algae	Halophilic, biofuel and beta-carotene production			Joint Genome Institute		Organelle genomes complete,[6] nuclear genome in progress
Micromonas pusilla CCMP1545	Green algae	Marine phytoplankton			Joint Genome Institute	2007[7][8]
Micromonas pusilla RCC299/NOUM17	Green algae	Marine phytoplankton			Joint Genome Institute	2007[8][9]
Ostreococcus lucimarinus CCE9901	Green algae	Simple eukaryote, small genome	13.2 Mb	7,796		2007[10]
Ostreococcus tauri OTH95	Green algae	Simple eukaryote, small genome				2006[11]
Ostreococcus sp. RCC809	Green algae			7,773	Joint Genome Institute	2008[12]
Volvox carteri	Green algae	Multicellular alga, model organism	~131.2 Mb	14,971		2010[13]
Chondrus crispus	Red algae		105 Mb	9,606	Genoscope/Station Biologique de Roscoff	2013[14]
Cyanidioschyzon merolae Strain:10D	Red algae	Photo-autotrophic	16.73 Mb	5,017		2004,[15] 2007 [16]
Galdieria sulphuraria	Red algae	Thermo-acidophilic (extremophile)	13.7 Mb	6,623		2005[17] 2005 [18] 2013 [19]
Porphyridium purpureum	Red algae		19.7 Mb	8,355		2013 [20]
Pyropia yezoensis	Red algae		43 Mb	10,327		2013 [21]
Ectocarpus siliculosus	Brown algae (Heterokontophyta)	distantly related to plants			Station Biologique de Roscoff	2010[22]

Bryophytes

Organism strain	Division	Relevance	Genome size	Number of genes predicted	Organization	Year of completion	Assembly status
Physcomitrella patens ssp. patens str. Gransden 2004	Bryophytes	Early diverging land plant				2008[23]

Higher plants (vascular plants)

Organism strain	Division	Relevance	Genome size	Number of genes predicted	Organization	Year of completion	Assembly status
Selaginella moellendorffii	Lycopodiophyta	Model organism				2011[24][25]

Angiosperms

Amborellales - amborellales#English - amborellales#Latin - Special:WhatLinksHere/Amborellales - Amborellales@WSp - Amborellales@WP - Google Amborellales (Books • Groups • Scholar) - Amborellales at List of Prokaryotic names with Standing in Nomenclature - Fossilworks

Organism strain	Family	Relevance	Genome size	Number of genes predicted	Organization	Year of completion	Assembly status
Amborella trichopoda	Amborellaceae	Basal angiosperm				2013[26][27]

Eudicots

Ranunculales

Organism strain	Family	Relevance	Genome size	Number of genes predicted	Organization	Year of completion	Assembly status
Aquilegia coerulea	Ranunculaceae	Basal eudicot				Unpublished[28]

Proteales

Organism strain	Family	Relevance	Genome size	Number of genes predicted	Organization	Year of completion	Assembly status
Nelumbo nucifera	Nelumbonaceae	Basal eudicot				2013[29]

Caryophyllales

Organism strain	Family	Relevance	Genome size	Number of genes predicted	Organization	Year of completion	Assembly status
Beta vulgaris (sugar beet)	Amaranthaceae (formerly Chenopodiaceae)	Crop plant	714–758 Mbp	27,421		2013[30]

Rosids

Organism strain	Family	Relevance	Genome size	Number of genes predicted	Organization	Year of completion	Assembly status
Betula nana (dwarf birch)	Betulaceae	Arctic shrub	450 Mbp		QMUL/SBCS	2013[31]
Aethionema arabicum	Brassicaceae	Comparative analysis of crucifer genomes				2013[32]
Arabidopsis lyrata	Brassicaceae	model plant				2011[33]
Arabidopsis thaliana Ecotype:Columbia	Brassicaceae	Model plant	135 Mbp			2000[34]
Brassica rapa (Chinese cabbage)	Brassicaceae	Assorted crops and model organism				2011[35]
Capsella rubella	Brassicaceae	Close relative of Arabidopsis thaliana	130Mbp	26,521	JGI	2013?[36] 2013[37]
Eutrema salsugineum	Brassicaceae	A relative of arabidopsis with high salt tolerance	240Mbp	26,351	JGI	2013[38]
Eutrema parvulum	Brassicaceae	Comparative analysis of crucifer genomes				2013[32]
Leavenworthia alabamica	Brassicaceae	Comparative analysis of crucifer genomes				2013[32]
Sisymbrium irio	Brassicaceae	Comparative analysis of crucifer genomes				2013[32]
Thellungiella parvula	Brassicaceae	A relative of arabidopsis with high salt tolerance				2011[39]
Cannabis sativa (hemp)	Cannabaceae	Hemp and marijuana production	ca 820Mbp	30,074 based on transcriptome assembly and clustering		2011[40]	Illumina/454 scaffold N50 16.2 Kbp
Carica papaya (papaya)	Caricaceae	Fruit crop	372Mbp	28,629		2008[41]	contig N50 11kbp scaffold N50 1Mbp total coverage ~3x (Sanger) 92.1% unigenes mapped 235Mbp anchored (of this 161Mbp also oriented)
Kalanchoe	Crassulaceae					2013?[42]
Citrullus lanatus (watermelon)	Cucurbitaceae	Tasty	ca 425Mbp	23,440	BGI	2012[43]	Illumina coverage 108.6x contig N50 26.38 kbp Scaffold N50 2.38 Mbp genome covered 83.2% ~97% ESTs mapped
Cucumis melo (Muskmelon) DHL92	Cucurbitaceae	Vegetable crop	450Mbp	27,427		2012[44]	454 13.5x coverage contig N50: 18.1kbp scaffold N50: 4.677 Mbp WGS
Cucumis sativus (cucumber) 'Chinese long' inbred line 9930	Cucurbitaceae	Vegetable crop	350 Mbp (Kmer depth) 367 Mbp (flow cytometry)	26,682		2009[45]	contig N50 19.8kbp scaffold N50 1,140kbp total coverage ~72.2 (Sanger + Ilumina) 96.8% unigenes mapped 72.8% of the genome anchored
Hevea brasiliensis (rubber tree)	Euphorbiaceae	the most economically important member of the genus Hevea				2013[46]
Jatropha curcas Palawan	Euphorbiaceae	bio-diesel crop				2010[47]
Manihot esculenta (Cassava)	Euphorbiaceae	Humanitarian importance	~760Mb	30,666	JGI	2012[48]
Ricinus communis (Castor bean)	Euphorbiaceae	Oilseed crop	320Mbp	31,237	JCVI	2010[49]	Sanger coverage~4.6x contig N50 21.1 kbp scaffold N50 496.5kbp
Cajanus cajan (Pigeon pea) var. Asha	Fabaceae	Model legume				2012[50][51]
Cicer arietinum (chickpea)	Fabaceae	filling				2013[52]
Cicer arietinum L. (chickpea)	Fabaceae					2013[53]
Glycine max (soybean) var. Williams 82	Fabaceae	Protein and oil crop	1115Mbp	46,430		2010[54]	Contig N50:189.4kbp Scaffold N50:47.8Mbp Sanger coverage ~8x WGS 955.1 Mbp assembled
Lotus japonicus (Bird's-foot Trefoil)	Fabaceae	Model legume				2008[55]
Medicago truncatula (Barrel Medic)	Fabaceae	Model legume				2011[56]
Phaseolus vulgaris (common bean)	Fabaceae	Model bean	520Mbp	31,638	JGI	2013?[57]
Linum usitatissimum (flax)	Linaceae	Crop	~350Mbp	43,384	BGI et al.	2012 [58]
Gossypium raimondii	Malvaceae	One of the putative progenitor species of tetraploid cotton				2013?[59]
Theobroma cacao (cocoa tree)	Malvaceae	Flavouring crop				2010[60][61]
Theobroma cacao (cocoa tree) cv. Matina 1-6	Malvaceae	Most widely cultivated cacao type				2013[62]
Azadirachta indica (neem)	Meliaceae	Source of number of Terpenoids, including biopesticide azadirachtin, Used in Traditional Medicine	364 Mbp	~20000	GANIT Labs	2012[63] and 2011[64]	Illumina GAIIx, scaffold N50 of 452028bp, Transcriptome data from Shoot, Root, Leaf, Flower and Seed
Eucalyptus grandis (Rose gum)	Myrtaceae	Fibre and timber crop				2011[65]
Fragaria vesca (wild strawberry)	Rosaceae	Fruit crop	240Mbp	34,809		2011[66]	scaffold N50: 1.3 Mbp 454/Illumina/solid 39x coverage WGS
Malus domestica (apple) "Golden Delicious"	Rosaceae	Fruit crop	~742.3Mbp	57,386		2010[67]	contig N50 13.4 (kbp??) scafold N50 1,542.7 (kbp??) total coverage ~16.9x (Sanger + 454) 71.2% anchored
Prunus amygdalus (almond)	Rosaceae	Fruit crop				2013?[68]
Prunus avium (sweet cherry) cv. Stella	Rosaceae	Fruit crop				2013?[68]
Prunus mume (Chinese plum or Japanese apricot)	Rosaceae	Fruit crop				2012[69]
Prunus persica (peach)	Rosaceae	Fruit crop	265Mbp	27,852		2013[70]	Sanger coverage:8.47x WGS ca 99% ESTs mapped 215.9 Mbp in pseudomolecules
Pyrus bretschneideri (ya pear or Chinese white pear) cv. Dangshansuli	Rosaceae	Fruit crop				2012[71]
Pyrus communis (European pear) cv. Doyenne du Comice	Rosaceae	Fruit crop				2013?[68]
Citrus clementina (Clementine)	Rutaceae	Fruit crop				2013?[72]
Citrus sinensis (Sweet orange)	Rutaceae	Fruit crop				2013?,[72] 2013[73]
Populus trichocarpa (poplar)	Salicaceae	Carbon sequestration, model tree, timber	510 Mbp (cytogenetic) 485 Mbp (coverage)	73,013 [Phytozome]		2006[74]	Scaffold N50: 19.5 Mbp Contig N50:552.8 Kbp [phytozome] WGS >=95 % cDNA found
Vitis vinifera (grape) genotype PN40024	Vitaceae	fruit crop				2007[75]

Asterids

Organism strain	Family	Relevance	Genome size	Number of genes predicted	Organization	Year of completion	Assembly status
Mimulus guttatus	Scrophulariaceae	model system for studying ecological and evolutionary genetics	ca 430Mbp	26,718	JGI	2013?[76]	Scaffold N50 = 1.1 Mbp Contig N50 = 45.5 Kbp
Solanum lycopersicum (tomato) cv. Heinz 1706	Solanaceae	Food crop	ca 900Mbp	34,727	SGN	2011[77] 2012[78]	Sanger/454/Illumina/Solid Pseudomolecules spanning 91 scaffolds (760Mbp of which 594Mbp have been oriented ) over 98% ESTs mappable
Solanum pimpinellifolium (Currant Tomato)	Solanaceae	closest wild relative to tomato				2012[78]	Illumina contig N50: 5100bp ~40x coverage
Solanum tuberosum (potato)	Solanaceae	Food crop	844 Mbp kmer (856 Mbp)	39,031	PGSC	2011[79]	Sanger/454/Illumina 79.2x coverage contig N50: 31,429bp scaffold N50: 1,318,511bp
Nicotiana benthamiana	Solanaceae	Close relative of tobacco	ca 3Gbp			2012[80]	Illumina 63x coverage contig N50: 16,480bp scaffold N50:89,778bp >93% unigenes found
Nicotiana sylvestris (Tobacco plant)	Solanaceae	model system for studies of terpenoid production	2.636Gbp		Philip Morris International	2013[81]	94x coverage scaffold N50: 79.7 kbp 194kbp superscaffolds using physical Nicotiana map
Nicotiana tomentosiformis	Solanaceae	Tobacco progenitor	2.682 Gb		Philip Morris International	2013[81]	146x coverage scaffold N50: 82.6 kb 166kbp superscaffolds using physical Nicotiana map
Capsicum annuum (Pepper) (a) cv. CM334 (b) cv. Zunla-1	Solanaceae	Food crop	~3.48 Gbp	(a) 34,903 (b) 35,336		(a) 2014[82] (b) 2014[83]	N50 contig: (a) 30.0 kb (b) 55.4 kb N50 scaffold: (a) 2.47 Mb (b) 1.23 Mb
Capsicum annuum var. glabriusculum (Chiltepin)	Solanaceae	Progenitor of cultivated pepper	~3.48 Gbp	34,476		2014[83]	N50 contig: 52.2 kb N50 scaffold: 0.45 Mb
Petunia	Solanaceae	Economically important flower				2011[84]
Utricularia gibba (humped bladderwort)	Lentibulariaceae	model system for studying genome size evolution; a carnivorous plant	81.87 Mb	28,494	LANGEBIO, CINVESTAV	2013[85]	Scaffold N50: 80.839 Kb

Monocots

Grasses

Organism strain	Family	Relevance	Genome size	Number of genes predicted	Organization	Year of completion	Assembly status
Setaria italica (Foxtail millet)	Poaceae	Model of C4 metabolism				2012[86]
Aegilops tauschii (Tausch's goatgrass)	Poaceae	bread wheat D-genome progenitor	ca 4.36Gb		BGI	2013[87]	Non-repetitive sequence assembled
Brachypodium distachyon (purple false brome)	Poaceae	Model monocot				2010[88]
Hordeum vulgare (barley)	Poaceae	Model of ecological adoption			IBSC	2012[89]
Oryza brachyantha (wild rice)	Poaceae	Disease resistant wild relative of rice				2013[90]
Oryza glaberrima (African rice) var CG14	Poaceae	West-African species of rice				2010[91]
Oryza sativa (short grain rice) ssp indica	Poaceae	Crop and model cereal				2002[92]
Oryza sativa (long grain rice) ssp japonica	Poaceae	Crop and model cereal				2002[93]
Panicum virgatum (switchgrass)	Poaceae	biofuel				2013?[94]
Phyllostachys edulis (moso bamboo)	Poaceae					2013[95]
Sorghum bicolor genotype BTx623	Poaceae	Crop	ca 730Mbp	34,496		2009[96]	contig N50:195.4kbp scaffold N50: 62.4Mbp Sanger, 8.5x coverage WGS
Triticum aestivum (bread wheat)	Poaceae	20% of global nutrition				2012[97]	Non-repetitive sequence assembled Roche 454/Illumina WGS
Triticum urartu	Poaceae	Bread wheat A-genome progenitor	ca 4.94Gb		BGI	2013[98]	Non-repetitive sequence assembled Illumina WGS
Zea mays ssp mays B73	Poaceae	Cereal crop	2,300Mbp	39,656[99]		2009[100]	contig N50 40kbp scaffold N50: 76kbp Sanger, 4-6x coverage per BAC

Other non-grasses

Organism strain	Family	Relevance	Genome size	Number of genes predicted	Organization	Year of completion	Assembly status
Musa acuminata (Banana)	Musaceae	A-genome of modern banana cultivars	523 Mbp	36,542		2012[101]	N50 contig: 43.1 kb N50 scaffold: 1.3 Mb
Musa balbisiana (Wild banana)	Musaceae	B-genome of modern banana cultivars	438 Mbp	36,638		2013[102]	N50 contig: 7.9 kb
Phoenix dactylifera (Date palm)	Arecaceae	Woody crop in arid regions	658 Mbp	28,800		2011[103]	N50 contig: 6.4 kb
Elaeis guineensis (African oil palm)	Arecaceae	Oil-bearing crop	~1800 Mbp	34,800		2013[104]	N50 scaffold: 1.27 Mb
Spirodela polyrhiza (Greater duckweed)	Araceae	Aquatic plant	158 Mbp	19,623		2014[105]	N50 scaffold: 3.76 Mb

Gymnosperms

Organism strain	Family	Relevance	Genome size	Number of genes predicted	Organization	Year of completion	Assembly status
Picea abies (Norway spruce)	Pinaceae	Timber, tonewood, ornamental such as Christmas tree	20 Gb	28,354	Umeå Plant Science Centre / SciLifeLab, Sweden	2013[106]
Picea glauca (White spruce)	Pinaceae	Timber, Pulp	20.8 Gb	56,064	Institutional Collaboration	2013[107]
Pinus taeda (Loblolly pine)	Pinaceae	Timber	20.15 Gb	50,172	Institutional collaboration	2014[108][109][110]	N50 scaffold size: 66.9 kbp

Uncategorised things to add...

the genome from Galdieria sulphuraria has finally been published (Schönknecht, G., W.-H. Chen, et al. (2013). "Gene transfer from bacteria and archaea facilitated evolution of an extremophilic eukaryote." Science 339(6124): 1207-1210.) Genome size is 13.7 MB, and 6623 protein-coding genes were annotated.

Nakamura et al. published the genome sequence for Pyropia yezoensis (Nakamura, Y., N. Sasaki, et al. (2013). "The first symbiont-free genome sequence of marine red alga, Susabi-nori Pyropia yezoensis." PLoS ONE 8(3): e57122.).

Bhattacharya et al. published the genome of Porphyridium purpureum (Bhattacharya, D., D. C. Price, et al. (2013). "Genome of the red alga Porphyridium purpureum." Nature Communications 4.)

Press releases announcing sequencing

Not meeting criteria of the first paragraph of this article in being nearly full sequences with high quality, published, assembled and publicly available. This list includes species where sequences are announced in press releases or websites, but not in a data-rich publication in a refereed Journal with doi.

• Brassica napus, oil plant (2009^[111])
• Elaeis guineensis, oil palm (2007^[112])
• Corchorus olitorius, fibre plant (2010^{[113][114][115]})
• Fraxinus excelsior, European ash (2013 draft ^[116][117])

See also

• List of sequenced plant genomes
  • Sequenced_plant_genomes
• List of sequenced eukaryotic genomes
• List of sequenced animal genomes
• List of sequenced archaeal genomes
• List of sequenced bacterial genomes
• List of sequenced fungi genomes
• List of sequenced plastomes
• List of sequenced protist genomes

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70. The International Peach Genome Initiative, et al. (2013) “The high-quality draft genome of peach (Prunus persica) identifies unique patterns of genetic diversity, domestication and genome evolution”, in Nature Genetics‎^[2], volume 45, number 5, →DOI, →PMID, pages 487–494
71. The genome of the pear (Pyrus bretschneideri Rehd.)
72. Phytozome v9.1: Citrus clementina
73. Xu Q, et al. (2013) “The draft genome of sweet orange (Citrus sinensis)”, in Nature Genetics, volume 45, number 1, →DOI, pages 59–66
74. Tuskan GA, Difazio S, Jansson S, et al. (2006 September) “The genome of black cottonwood, Populus trichocarpa (Torr. & Gray)”, in Science, volume 313, number 5793, →Bibcode, →DOI, →PMID, pages 1596–604
75. Jaillon O, Aury JM, Noel B, et al. (2007 September) “The grapevine genome sequence suggests ancestral hexaploidization in major angiosperm phyla”, in Nature, volume 449, number 7161, →Bibcode, →DOI, →PMID, pages 463–7
76. Phytozome v9.1: Mimulus guttatus
77. Sol Genomics Network
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79. Template:cite doi
80. A draft genome sequence of Nicoti... [Mol Plant Microbe Interact. 2012] - PubMed - NCBI
81. Genome Biology | Abstract | Reference genomes and transcriptomes of Nicotiana sylvestris and Nicotiana tomentosiformis
82. Kim et al. (2014) “Genome sequence of the hot pepper provides insights into the evolution of pungency in Capsicum species”, in Nature Genetics, volume 46, number 3, →DOI, pages 270-278
83. Qin et al. (2014) “Whole-genome sequencing of cultivated and wild peppers provides insights into Capsicum domestication and specialization.”, in Proc Natl Acad Sci U S A, volume 111, →DOI, pages 5135-5140
84. The Petunia Platform - Home
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88. The International Brachypodium Initiative (2009 December) “Genome sequencing and analysis of the model grass Brachypodium distachyon”, in Nature, volume 463, number 7282, →Bibcode, →DOI, →PMID, pages 763–8
89. The International Barley Genome Sequencing Consortium ((Can we date this quote?)) “A physical, genetic and functional sequence assembly of the barley genome”, in Nature, volume 491, number 7426, →Bibcode, →DOI
90. Whole-genome sequencing of Oryza brachyantha reveals mechanisms underlying Oryza genome evolution : Nature Communications : Nature Publishing Group
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94. Phytozome v9.1: Panicum virgatum
95. The draft genome of the fast-growing non-timber forest species moso bamboo (Phyllostachys heterocycla) : Nature Genetics : Nature Publishing Group
96. Template:cite doi
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98. Ling H-QZhou SLiu Det al. (2013) “Draft genome of the wheat A-genome progenitor Triticum urartu”, in Nature, volume 496, number 7443, →Bibcode, →DOI
99. MaizeSequence 5b.60: Home
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101. D’Hont et al. (2012) “The banana (Musa acuminata) genome and the evolution of monocotyledonous plants”, in Nature, volume 488, number 7410, →Bibcode, →DOI, →PMID, pages 213–217
102. Davey et al. (2013) “A draft Musa balbisiana genome sequence for molecular genetics in polyploid, inter- and intra-specific Musa hybrids.”, in BMC Genomics, volume 14, →DOI, page 683
103. Al-Dous et al. (2011) “De novo genome sequencing and comparative genomics of date palm (Phoenix dactylifera)”, in Nature Biotechnology, volume 29, number 6, →DOI, pages 521–527
104. Singh et al. (2013) “Oil palm genome sequence reveals divergence of interfertile species in Old and New worlds.”, in Nature, volume 500, number 7462, →DOI, pages 335-339
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106. Nystedt, Björn with Street, Nathaniel R., Wetterbom, Anna, Zuccolo, Andrea, Lin, Yao-Cheng, Scofield, Douglas G., Vezzi, Francesco, Delhomme, Nicolas, Giacomello, Stefania, Alexeyenko, Andrey, Vicedomini, Riccardo, Sahlin, Kristoffer, Sherwood, Ellen, Elfstrand, Malin, Gramzow, Lydia, Holmberg, Kristina, Hällman, Jimmie, Keech, Olivier, Klasson, Lisa, Koriabine, Maxim, Kucukoglu, Melis, Käller, Max, Luthman, Johannes, Lysholm, Fredrik, Niittylä, Totte, Olson, Åke, Rilakovic, Nemanja, Ritland, Carol, Rosselló, Josep A., Sena, Juliana, Svensson, Thomas, Talavera-López, Carlos, Theißen, Günter, Tuominen, Hannele, Vanneste, Kevin, Wu, Zhi-Qiang, Zhang, Bo, Zerbe, Philipp, Arvestad, Lars, Bhalerao, Rishikesh, Bohlmann, Joerg, Bousquet, Jean, Garcia Gil, Rosario, Hvidsten, Torgeir R., de Jong, Pieter, MacKay, John, Morgante, Michele, Ritland, Kermit, Sundberg, Björn, Lee Thompson, Stacey, Van de Peer, Yves, Andersson, Björn, Nilsson, Ove, Ingvarsson, Pär K., Lundeberg, Joakim, and Jansson, Stefan (2013) “The Norway spruce genome sequence and conifer genome evolution”, in Nature, volume 497, number 7451, →DOI, →PMID, pages 579–584
107. Birol, Inanc with Raymond, Anthony, Jackman, Shaun D., Pleasance, Stephen, Coope, Robin, Taylor, Greg A., Yuen, Macaire M.S., Keeling, Christopher I., Brand, Dana, Vandervalk, Benjamin P., Kirk, Heather, Pandoh, Pawan, Moore, Richard A., Zhao, Yongjun, Mungall, Andrew J., Jaquish, Barry, Yanchuk, Alvin, Ritland, Carol, Boyle, Brian, Bousquet, Jean, Ritland, Kermit, MacKay, John, Bohlmann, Jörg, and Jones, Steven J.M. (2013) “Assembling the 20 Gb white spruce (Picea glauca) genome from whole-genome shotgun sequencing data”, in Bioinformatics, volume 29, number 12, →DOI, →PMID, pages 1492-1497
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111. http://www.research-in-germany.de/coremedia/generator/dachportal/en/07__News_20and_20Events/VDITZ_20-_20News_26Events/Archiv/2009-10-25_2C_20Full_20oilseed_20rape_20genome_20deciphered,sourcePageId=34814.html
112. “First Draft Of Oil Palm Genome Completed”, in (Please provide the book title or journal name)‎^[4], Energy-daily.com, 2010 August 27 (last accessed)
113. “Jute genome decoded : Golden fibre to become healthy, high yielding, weather-tolerant; Hawaii-based Bangladeshi scientist leads team to landmark discovery”, in (Please provide the book title or journal name)‎^[5], The Daily Star, (Can we date this quote?)
114. “Jute genome sequence decoded by Bangladeshi scientists”, in (Please provide the book title or journal name)‎^[6], Hindusthan Times, (Can we date this quote?)
115. “স্বপ্নযাত্রা (Chasing the dream)”, in (Please provide the book title or journal name)‎^[7], Jute Genome Project, (Can we date this quote?)
116. Welcome to the British Ash Tree Genome Project | The British Ash Tree Genome Project -
     The School of Biological & Chemical Sciences
117. BBC News - Ash genome reveals fungus resistance