The B73 Maize Genome: Complexity, Diversity, and Dynamics

Schnable, Patrick S.; Ware, Doreen; Fulton, Robert S.; Stein, Joshua C.; Wei, Fusheng; Pasternak, Shiran; Liang, Chengzhi; Zhang, Jianwei; Fulton, Lucinda L.; Graves, Tina; Minx, Patrick; Reily, Amy Denise; Courtney, Laura; Kruchowski, Scott; Tomlinson, Chad; Strong, Cindy; Delehaunty, Kim D.; Fronick, Catrina C.; Courtney, Bill; Rock, Susan M.; Belter, Eddie; Du, Feiyu; Kim, Kyung; Abbott, Rachel M.; Cotton, Marc; Levy, Andy; Marchetto, Pamela; Ochoa, Kerri; Jackson, Stephanie; Gillam, Barbara; Chen, Weizu; Yan, Le; Higginbotham, Jamey; Cardenas, Marco; Waligorski, Jason; Applebaum, Elizabeth; Phelps, Lindsey; Falcone, Jason; Kanchi, Krishna L.; Thane, Thynn; Scimone, Adam; Thane, Nay; Henke, Jessica; Wang, Tom; Ruppert, Jessica; Shah, Neha; Rotter, Kelsi; Hodges, Jennifer; Ingenthron, Elizabeth; Cordes, Matt; Kohlberg, Sara; Sgro, Jennifer; Delgado, Brandon; Mead, Kelly; Chinwalla, Asif T.; Leonard, Shawn; Crouse, Kevin; Collura, Kristi; Kudrna, Dave; Currie, Jennifer; He, Rong; Angelova, Angelina; Rajasekar, Shanmugam; Mueller, Teri; Lomeli, Rene; Scara, Gabriel; Ko, Ara; Delaney, Krista; Wissotski, Marina; López, Georgina Espinosa; Campos, David; Braidotti, Michele; Ashley, Elizabeth; Golser, Wolfgang; Kim, Hye‐Ran; Lee, Seung‐Hee; Lin, Juan; Dujmic, Zeljko; Kim, Woojin; Talag, Jayson; Zuccolo, Andrea; Fan, Chuanzhu; Sebastian, Aswathy; Kramer, Melissa; Spiegel, Lori; Nascimento, Lidia; Zutavern, Theresa; Miller, Beth A.; Ambroise, Claude; Muller, Stéphanie; Will, Stefan; Narechania, Apurva; Ren, Liya; Wei, Sharon; Kumari, Sunita; Faga, Ben; Levy, Michael J.; McMahan, Linda; Buren, Peter Van; Vaughn, Matthew; Ying, Kai; Yeh, Cheng‐Ting; Emrich, Scott J.; Jia, Yi; Kalyanaraman, Ananth; Hsia, An Ping; Barbazuk, W. Brad; Baucom, Regina S.; Brutnell, Thomas P.; Carpita, Nicholas C.; Chaparro, Cristian; Chia, Jer Ming; Deragon, Jean-Marc; Estill, James C.; Fu, Yan; Jeddeloh, Jeffrey A.; Han, Yujun; Lee, Hyeran; Li, Pinghua; Lisch, Damon; Liu, Sanzhen; Liu, Zhijie; Nagel, Dawn H.; McCann, Maureen C.; SanMiguel, Phillip; Myers, Alan M.; Nettleton, Dan; Nguyen, John D.; Penning, Bryan W.; Ponnala, Lalit; Schneider, Kevin; Schwartz, David C.; Sharma, Anupma; Soderlund, Carol; Springer, Nathan M.; Sun, Qi; Wang, Hao; Waterman, Michael S.; Westerman, Richard P.; Wolfgruber, Thomas; Yang, Lixing; Yu, Yeisoo; Zhang, Lifang; Zhou, Shiguo; Zhu, Qihui; Bennetzen, Jeffrey L.; Dawe, R. Kelly; Jiang, Jiming; Jiang, Ning; Presting, Gernot G.; Wessler, Susan R.; Aluru, Srinivas; Martienssen, Robert A.; Clifton, Sandra W.; McCombie, W. Richard; Wing, Rod A.; Wilson, Richard K.

doi:10.1126/science.1178534

Cited by 3,572 publications

(3,337 citation statements)

References 45 publications

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“…Despite the sequencing of the maize genome in 2009 [6], comparatively little is known about the high levels of genetic diversity that exist between the many maize inbred lines. To address this, Romay et al [7] perform genotyping-by-sequencing of 681,257 SNP markers in the 2,815 maize accessions in the USA national maize inbred seed bank.…”

Section: Crop Genomics: Growing Potentialmentioning

confidence: 99%

Plant genomics: sowing the seeds of success

Bilsborough

2013

Genome Biol

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Section: Crop Genomics: Growing Potentialmentioning

confidence: 99%

Plant genomics: sowing the seeds of success

Bilsborough

2013

Genome Biol

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“…The first free-living organisms were sequenced less than 20 years ago, starting with simple microbial genomes [7], and increasing in complexity to the first eukaryotic genomes [8], the first multicellular species [9], and then on to plant genomes, including Arabidopsis thaliana (thale cress) [10], Oryza sativa (rice) [11], Carica papaya (papaya) [12] and Zea mays (maize) in 2009 [13], using first-generation capillary sequencing. Since then many others have been sequenced leveraging second-generation sequencing, including Fragaria vesca (strawberry) [14], Solanum lycopersicum (tomato) [15] and Cajanus cajan (pigeonpea) [16], and dozens more are nearing completion [17].…”

mentioning

confidence: 99%

“…This increase in sequenced plant genomes has largely been driven by technological improvements: whereas the first generation of automated DNA sequencing instruments could sequence thousands of base pairs per day, current state-of-the-art second-generation sequencing instruments can sequence many billions of bases per day for hundreds or thousands of dollars per gigabase instead of millions or billions of dollars per gigabase [18]. These technologies have been applied to study thousands of genomes across the tree of life, enabling rich annotation of their gene networks [19], the development of comparative genomics approaches to infer evolutionary and domestication forces [13], the cataloging of genomic markers to optimize plant breeding [20], and numerous other studies that use the genome sequence as the backbone of the analysis [21]. …”

mentioning

confidence: 99%

“…In addition they can have much higher ploidy, which is estimated to occur in up to 80% of all plant species [29], and higher rates of heterozygosity and repeats [30] than their counterparts in other kingdoms. Furthermore, the gene content in plants can be very complex, as shown by the presence of large gene families and abundant pseudogenes with nearly identical sequences derived from recent whole genome duplication events and transposon activity [13]. Plants tend to have high copy chloroplasts and mitochondria organelles, which complicate assembly of their remnants in the nuclear genome and skew coverage levels [12].…”

mentioning

confidence: 99%

“…Instead of large contigs and scaffolds spanning large chromosome regions seen in recent vertebrate genome assemblies [31], there is a greater chance to assemble the sequencing reads into isolated gene islands among the background of high copy repeats [13]. Furthermore, the gene sequences may not always be correct, considering that nearly identical gene families are notoriously difficult to assemble and may collapse into a mosaic sequence without necessarily representing any member of the family [32].…”

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Current challenges in de novo plant genome sequencing and assembly

2012

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Plant Transposable Elements

Jiang

2016

Encyclopedia of Life Sciences

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Transposable elements (TEs) were first discovered by Barbara McClintock in maize. As the most abundant and dynamic component of the plant genomes, the activity of TEs is responsible for genome size expansion, alteration of gene expression, duplication and amplification of normal genes. There are many different types of elements in the plant genomes, with each of them occupying a specific niche, including genic regions, intergenic regions and centromeres. Particularly, the centromere‐specific elements may play critical roles in the formation of new plant species. Most TEs are quiescent in normal development but are turned on by various biotic or abiotic stresses, thus favouring the survival of host organisms under undesirable conditions. In addition to their roles in genome evolution, TEs can be useful tools for gene cloning, mapping and transformation. Key Concepts Transposable elements are the largest components of plant genomes. They have target specificity. Transposable elements play roles in speciation. Transposition activity is tightly regulated. Transposable elements influence expression of other genes. They are genetic and molecular tools.

show abstract

The B73 Maize Genome: Complexity, Diversity, and Dynamics

Cited by 3,572 publications

References 45 publications

Plant genomics: sowing the seeds of success

Plant genomics: sowing the seeds of success

Current challenges in de novo plant genome sequencing and assembly

Plant Transposable Elements

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