The tomato genome sequence provides insights into fleshy fruit evolution

Sato, Shusei; Tabata, Satoshi; Hirakawa, Hideki; Asamizu, Erika; Shirasawa, Kenta; Isobe, Sachiko; Kaneko, Takakazu; Nakamura, Yasukazu; Shibata, Daisuke; Aoki, Koh; Egholm, Michael; Knight, James; Bogden, Robert; Li, Changbao; Yang, Shuang; Xu, Xun; Pan, Shengkai; Cheng, Shifeng; Liu, Xin; Ren, Yuanyuan; Wang, Jun; Albiero, Alessandro; Pero, Francesca Dal; Todesco, Sara; Eck, Joyce Van; Buels, Robert; Bombarely, Aureliano; Gosselin, J.; Huang, Minyun; Leto, Jonathan A.; Menda, Naama; Strickler, Susan R.; Mao, Linyong; Gao, Shan; Tecle, Isaak Y.; York, A.; Zheng, Yi; Vrebalov, Julia; Lee, Jemin; Zhong, Silin; Mueller, Lukas A.; Stiekema, Willem J.; Ribeca, Paolo; Alioto, Tyler; Yang, Wencai; Huang, Sanwen; Du, Yan; Zhang, Zhonghua; Gao, Jianchang; Guo, Yanmei; Wang, Xiaoxuan; Li, Ying; He, Jun; Li, Chuanyou; Cheng, Zhihui; Zuo, Jianru; Ren, Jianfeng; Zhao, Jiuhai; Yan, Liuhua; Jiang, Hongling; Wang, Bao; Li, Hongshuang; Li, Zhenjun; Fu, Fuyou; Chen, Bingtang; Han, Bin; Feng, Qi; Fan, Danlin; Wang, Mengying; Ling, Hong‐Qing; Xue, Yongbiao; Ware, Doreen; McCombie, W. Richard; Lippman, Zachary B.; Chia, Jer Ming; Jiang, Ke; Pasternak, Shiran; Gelley, Laura; Kramer, Melissa; Anderson, Lorinda K.; Chang, Song Bin; Royer, Suzanne M.; Shearer, Lindsay A.; Stack, Stephên M.; Rose, Jocelyn K. C.; Xu, Youqiang; Eannetta, Nancy T.; Matas, Antonio J.; McQuinn, Ryan P.; Tanksley, Steven D.; Câmara, Francisco; Guigó, Roderic; Rombauts, Stéphane; Fawcett, Jeffrey A.; Peer, Yves Van de; Zamir, Dani; Liang, Chunbo; Spannagl, Manuel; Gundlach, Heidrun; Bruggmann, Rémy; Mayer, Klaus; Jia, Zhiqi; Zhang, Mengjie; Ye, Zhibiao; Bishop, Gerard J.; Butcher, Sarah; López-Cobollo, Rosa; Buchan, Daniel W. A.; Filippis, Ioannis; Abbott, James; Singh, Manju; Singh, Archana; Pal, Jitendra Kumar; Pandit, Awadhesh; Singh, Pradeep Kumar; Mahato, Ajay Kumar; Dogra, Vivek; Gaikwad, Kishor; Sharma, Tilak Raj; Mohapatra, Trilochan; Singh, Nagendra; Causse, Mathilde; Rothan, Christophe; Noirot, Céline; Bellec, Arnaud; Klopp, Christophe; Delalande, Corinne; Bergès, Hélène; Mariette, Jérôme; Frasse, Pierre; Vautrin, Sonia; Zouine, Toulouse Mohamed; Latché, Alain; Rousseau, Christine; Regad, Farid; Pech, J. C.; Philippot, Murielle; Bouzayen, Mondher; Péricard, Pierre; Osorio, Sonia; Carmen, Asuncion Fernandez Del; Monforte, Antonio J.; Granell, Antonio; Fernández-Muñoz, Rafael; Conte, Mariana; Lichtenstein, Gabriel; Carrari, Fernando; Bellis, Gianluca De; Fuligni, Fabio; Peano, Clelia; Grandillo, Silvana; Termolino, Pasquale; Pietrella, Marco; Fantini, Elio; Falcone, Giulia; Fiore, Alessia; Giuliano, Giovanni; Lopez, Loredana; Facella, Paolo; Perrotta, Gaetano; Daddiego, Loretta; Bryan, Glenn; Orozco, Biology Modesto; Pastor, Xavier; Torrents, David; Schriek, Marco G.M. Van; Feron, Richard; Oeveren, Jan van; Heer, Peter De; Ponte, Lorena Da; Jacobs-Oomen, Saskia; Cariaso, Mike; Prins, Marcel; Eijk, Michiel J. T. van; Janssen, Antoine; Haaren, J. J. Van; HwanJo, Sung; Kim, Jung-Eun; Kwon, Suk‐Yoon; Kim, Sangmi; Koo, Dal Hoe; Lee, Sanghyeob; Clouser, Christopher R.; Rico, Alain; Hallab, Asis; Gebhardt, Christiane; Klee, Kathrin; Jöcker, Anika; Warfsmann, Jens; Göbel, Ulrike; Kawamura, Shingo; Yano, Kentarô; Sherman, Jamie; Fukuoka, Hiroyuki; Negoro, Satomi; Bhutty, Sarita; Chowdhury, Parul; Chattopadhyay, Debasis; Datema, Erwin; Smit, Sandra; Schijlen, Elio; Belt, José van de; Haarst, Jan C. van; Peters, Sander; Staveren, Marjo J. van; Henkens, M. H. C.; Mooyman, Paul; Hesselink, Thamara; Ham, Roeland C. H. J. van; Jiang, Guoyong; Droege, Marcus; Choi, Doil; Kang, Byung Cheol; Kim, Byung Dong; Park, Minkyu; Kim, Seungill; Yeom, Seon-In; Lee, Yong Hwan; Choi, Yang Do; Li, Guangcun; Gao, Jianwei; Liu, Yongsheng; Huang, Sheng‐Xiong; Fernández‐Pedrosa, Victoria; Collado, C.; Iga, Sheila Zuñ; Wang, Guoping; Cade, Rebecca; Dietrich, Robert A.; Rogers, Jane; Knapp, Sandra; Fei, Zhangjun; White, Ruth; Thannhauser, Theodore W.; Giovannoni, James J.; Botella, Miguel A.; Gilbert, Louise; Gonzalez, Fabra Ramon; Goicoechea, José Luis; Yu, Yun William; Kudrna, David; Collura, Kristi; Wissotski, Marina; Wing, Rod A.; Meyers, Blake C.; Gurazada, Aishwarya Bala; Green, Pamela J.; Mathur, Saloni; Vyas, Shailendra; Solanke, Amolkumar U.; Kumar, Rahul; Gupta, Vikrant; Sharma, Arun Kumar; Khurana, Paramjit; Khurana, Jitendra P.; Tyagi, Akhilesh K.; Dalmay, Tamás; Mohorianu, Irina; Walts, Brandon; Chamala, Srikar; Barbazuk, W. Brad; Li, Jingping; Guo, Hui; Lee, Tae Ho; Wang, Yupeng; Zhang, Dong; Paterson, Andrew H.; Wang, Xiyin; Tang, Haibao; Barone, Amalia; Chiusano, Maria Luisa; Ercolano, Maria Raffaella; D’Agostino, Nunzio; Filippo, Miriam Di; Traini, Alessandra; Sanseverino, Walter; Frusciante, Luigi; Seymour, Graham B.; Elharam, Mounir; Fu, Ying; Hua, Axin; Kenton, Steven; Lewis, Jennifer D.; Lin, Shaoping; Najar, Fares Z.; Lai, Hongshing; Qin, Baifang; Shi, Ruihua; Qu, Chunmei; White, Douglas W.; White, James D.; Xing, Yanbo; Yang, Keqin; Yi, Jing; Yao, Ziyun; Zhang, Liping; Roe, Bruce A.; Vezzi, Alessandro; D’Angelo, Michela; Zimbello, Rosanna; Schiavon, Riccardo; Caniato, Elisa; Rigobello, Chiara; Campagna, Davide; Vitulo, Nicola; Valle, Giorgio; Nelson, David R.; Paoli, Emanuele De; Szinay, Dóra; Jong, Hans H. De; Bai, Yuling; Visser, Richard G. F.; Lankhorst, Reném Klein; Beasley, Helen; McLaren, Karen; Nicholson, Christine; Riddle, Claire; Gianese, Giulio

doi:10.1038/nature11119

Cited by 2,628 publications

(1,492 citation statements)

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(32 reference statements)

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“…Protein identification and quantification were carried out using maxquant software version 1.4.1.2 (Cox & Mann, 2008). Raw MS data files were searched against a combined S. lycopersicum (Tomato Genome, 2012) and P. capsici (Lamour et al ., 2012) genome file (Notes S1) and quantification data were acquired using the label‐free quantification tool (LFQ) within maxquant (settings outlined in Notes S2) (Cox et al ., 2014). Full details of how maxquant generates peak lists and determines false discovery rates are detailed in Cox & Mann (2008).…”

Section: Methodsmentioning

confidence: 99%

“…A detailed description, including scripts used and analysed data, can be found on the GitHub page (Stam, 2015). In short, amino acid sequences for those proteins identified by MS were extracted from the SOL genomics protein database v. ITAG2.4 (Tomato Genome, 2012). This data set was subjected to predictnls (default settings) (Cokol et al ., 2000) and nlstradamus (two‐state model; posterior threshold 0.6) (Nguyen Ba et al ., 2009) to identify proteins with nuclear localization signals, and the Nucleolar Localization Sequence Detector ( nod ) (default settings) (Scott et al ., 2010, 2011) to identify proteins with nucleolar localization signals.…”

Section: Methodsmentioning

confidence: 99%

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Quantitative analysis of the tomato nuclear proteome during Phytophthora capsici infection unveils regulators of immunity

et al. 2017

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Summary Plant–pathogen interactions are complex associations driven by the interplay of host and microbe‐encoded factors. With secreted pathogen proteins (effectors) and immune signalling components found in the plant nucleus, this compartment is a battleground where susceptibility is specified. We hypothesized that, by defining changes in the nuclear proteome during infection, we can pinpoint vital components required for immunity or susceptibility.We tested this hypothesis by documenting dynamic changes in the tomato (Solanum lycopersicum) nuclear proteome during infection by the oomycete pathogen Phytophthora capsici. We enriched nuclei from infected and noninfected tissues and quantitatively assessed changes in the nuclear proteome. We then tested the role of candidate regulators in immunity through functional assays.We demonstrated that the host nuclear proteome dynamically changes during P. capsici infection. We observed that known nuclear immunity factors were differentially expressed and, based on this observation, selected a set of candidate regulators that we successfully implicated in immunity to P. capsici.Our work exemplifies a powerful strategy to gain rapid insight into important nuclear processes that underpin complex crop traits such as resistance. We have identified a large set of candidate nuclear factors that may underpin immunity to pathogens in crops.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Quantitative analysis of the tomato nuclear proteome during Phytophthora capsici infection unveils regulators of immunity

et al. 2017

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“…The transcriptome dataset is a valuable resource not only for the construction of expression profiles but also for novel gene discovery as well as for a large number of simple sequence repeat (SSR) and single nucleotide polymorphism (SNP) markers, which are highly useful for variety identification, population structure analysis, and linkage map development, and will contribute to the acceleration of breeding programs. To date, certain important plants of the Solanaceae family have been sequenced, such as the tomato and the potato (Xu et al, 2011;Sato et al, 2012). The deep RNAsequencing of L. ruthenicum will aid in understanding the key aspects of the biology and evolution of Lyceum, especially the molecular basis underlying its high saline-alkaline stress tolerance.…”

Section: Introductionmentioning

confidence: 99%

Physiological characterization, transcriptomic profiling, and microsatellite marker mining of Lycium ruthenicum

Chen

Zhang

et al. 2017

J. Zhejiang Univ. Sci. B

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Lycium ruthenicum is a perennial shrub species that has attracted considerable interest in recent years owing to its nutritional value and ability to thrive in a harsh environment. However, only extremely limited transcriptomic and genomic data related to this species can be found in public databases, thereby limiting breeding research and molecular function analysis. In this study, we characterized the physiological and biochemical responses to salinealkaline mixed stress by measuring photochemical efficiency, chlorophyll content, and protective enzyme activity. We performed global transcriptomic profiling analysis using the Illumina platform. After optimizing the assembly, a total of 68 063 unique transcript sequences with an average length of 877 bp were obtained. Among these sequences, 4096 unigenes were upregulated and 4381 unigenes were down-regulated after saline-alkaline mixed treatment. The most abundant transcripts and over-represented items were assigned to gene ontology (GO) terms or Kyoto Encyclopedia of Genes and the Genomes (KEGG) categories for overall unigenes, and differentially expressed unigenes were analyzed in detail. Based on this set of RNA-sequencing data, a total of 9216 perfect potential simple sequence repeats (SSRs) were identified within 7940 unigenes with a frequency of 1/6.48 kb. A total of 77 primer pairs were synthesized and examined in wet-laboratory experiments, of which 68 loci (88.3%) were successfully amplified with specific products. Eleven pairs of polymorphic primers were verified in 225 individuals from nine populations. The inbreeding coefficient and the polymorphism information content value ranged from 0.011 to 0.179 and from 0.1112 to 0.6750, respectively. The observed and expected heterozygosities ranged from 0.064 to 0.840 and from 0.115 to 0.726, respectively. Nine populations were clustered into three groups based on a genetic diversity study using these novel markers. Our data will be useful for functional genomic investigations of L. ruthenicum and could be used as a basis for further research on the genetic diversity, genetic differentiation, and gene flow of L. ruthenicum and other closely related species.

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“…Solanaceous crop genomics is in an exciting phase of development following the recent sequencing of the potato and tomato genomes [6,7]. Tomato ( Solanum lycopersicum L.), originated in South America, and was spread around the world to become one of the most extensively used vegetable crops.…”

Section: Tomato Genetics and Genomics: Past And Presentmentioning

confidence: 99%