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1. ABCB-mediated shootward auxin transport feeds into the root clock.

Author

Chen, Jian, Hu, Yangjie, Hao, Pengchao, Tsering, Tashi, Xia, Jian, Zhang, Yuqin, Roth, Ohad, Njo, Maria, Sterck, Lieven, Hu, Yun, Geelen, Danny, Geisler, Markus, Shani, Eilon, Beeckman, Tom, Vanneste, Steffen, and Zhao, Yunde

Subjects
ABCB, auxin transport, lateral root, root meristem, Arabidopsis Proteins, Arabidopsis, Biological Transport, Membrane Transport Proteins, Indoleacetic Acids, Plant Roots, Gene Expression Regulation, Plant
Abstract

Although strongly influenced by environmental conditions, lateral root (LR) positioning along the primary root appears to follow obediently an internal spacing mechanism dictated by auxin oscillations that prepattern the primary root, referred to as the root clock. Surprisingly, none of the hitherto characterized PIN- and ABCB-type auxin transporters seem to be involved in this LR prepatterning mechanism. Here, we characterize ABCB15, 16, 17, 18, and 22 (ABCB15-22) as novel auxin-transporting ABCBs. Knock-down and genome editing of this genetically linked group of ABCBs caused strongly reduced LR densities. These phenotypes were correlated with reduced amplitude, but not reduced frequency of the root clock oscillation. High-resolution auxin transport assays and tissue-specific silencing revealed contributions of ABCB15-22 to shootward auxin transport in the lateral root cap (LRC) and epidermis, thereby explaining the reduced auxin oscillation. Jointly, these data support a model in which LRC-derived auxin contributes to the root clock amplitude.

Published
2023

2. Maritime Pine Genomics in Focus

Author

Sterck, Lieven, de María, Nuria, Cañas, Rafael A., de Miguel, Marina, Perdiguero, Pedro, Raffin, Annie, Budde, Katharina B., López-Hinojosa, Miriam, Cantón, Francisco R., Rodrigues, Andreia S., Morcillo, Marian, Hurel, Agathe, Vélez, María Dolores, de la Torre, Fernando N., Modesto, Inês, Manjarrez, Lorenzo Federico, Pascual, María Belén, Alves, Ana, Mendoza-Poudereux, Isabel, Díaz, Marta Callejas, Pizarro, Alberto, El-Azaz, Jorge, Hernández-Escribano, Laura, Guevara, María Ángeles, Majada, Juan, Salse, Jerome, Grivet, Delphine, Bouffier, Laurent, Raposo, Rosa, De La Torre, Amanda R., Zas, Rafael, Cabezas, José Antonio, Ávila, Concepción, Trontin, Jean-Francois, Sánchez, Leopoldo, Alía, Ricardo, Arrillaga, Isabel, González-Martínez, Santiago C., Miguel, Célia, Cánovas, Francisco M., Plomion, Christophe, Díaz-Sala, Carmen, Cervera, María Teresa, Kole, Chittaranjan, Series Editor, and De La Torre, Amanda R., editor

Published
2022
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3. The Plant PTM Viewer 2.0: in-depth exploration of plant protein modification landscapes.

Author

Willems, Patrick, Sterck, Lieven, Dard, Avilien, Huang, Jingjing, Smet, Ive De, Gevaert, Kris, and Breusegem, Frank Van

Subjects
*POST-translational modification, *NUCLEAR proteins, *PLANT proteins, *PLANT enzymes, *GENETIC transcription regulation
Abstract

Post-translational modifications (PTMs) greatly increase protein diversity and functionality. To help the plant research community interpret the ever-increasing number of reported PTMs, the Plant PTM Viewer (https://www.psb.ugent.be/PlantPTMViewer) provides an intuitive overview of plant protein PTMs and the tools to assess it. This update includes 62 novel PTM profiling studies, adding a total of 112 000 modified peptides reporting plant PTMs, including 14 additional PTM types and three species (moss, tomato, and soybean). Furthermore, an open modification re-analysis of a large-scale Arabidopsis thaliana mass spectrometry tissue atlas identified previously uncharted landscapes of lysine acylations predominant in seed and flower tissues and 3-phosphoglycerylation on glycolytic enzymes in plants. An extra 'Protein list analysis' tool was developed for retrieval and assessing the enrichment of PTMs in a protein list of interest. We conducted a protein list analysis on nuclear proteins, revealing a substantial number of redox modifications in the nucleus, confirming previous assumptions regarding the redox regulation of transcription. We encourage the plant research community to use PTM Viewer 2.0 for hypothesis testing and new target discovery, and also to submit new data to expand the coverage of conditions, plant species, and PTM types, thereby enriching our understanding of plant biology. [ABSTRACT FROM AUTHOR]

Published
2024
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4. Transcriptional chronology reveals conserved genes involved in pennate diatom sexual reproduction.

Author

Audoor, Sien, Bilcke, Gust, Pargana, Katerina, Belišová, Darja, Thierens, Sander, Van Bel, Michiel, Sterck, Lieven, Rijsdijk, Nadine, Annunziata, Rossella, Ferrante, Maria Immacolata, Vandepoele, Klaas, and Vyverman, Wim

Subjects
DIATOMS, GENE expression, LIFE cycles (Biology), GENES, CELL size, PLANT reproduction
Abstract

Sexual reproduction is a major driver of adaptation and speciation in eukaryotes. In diatoms, siliceous microalgae with a unique cell size reduction‐restitution life cycle and among the world's most prolific primary producers, sex also acts as the main mechanism for cell size restoration through the formation of an expanding auxospore. However, the molecular regulators of the different stages of sexual reproduction and size restoration are poorly explored. Here, we combined RNA sequencing with the assembly of a 55 Mbp reference genome for Cylindrotheca closterium to identify patterns of gene expression during different stages of sexual reproduction. These were compared with a corresponding transcriptomic time series of Seminavis robusta to assess the degree of expression conservation. Integrative orthology analysis revealed 138 one‐to‐one orthologues that are upregulated during sex in both species, among which 56 genes consistently upregulated during cell pairing and gametogenesis, and 11 genes induced when auxospores are present. Several early, sex‐specific transcription factors and B‐type cyclins were also upregulated during sex in other pennate and centric diatoms, pointing towards a conserved core regulatory machinery for meiosis and gametogenesis across diatoms. Furthermore, we find molecular evidence that the pheromone‐induced cell cycle arrest is short‐lived in benthic diatoms, which may be linked to their active mode of mate finding through gliding. Finally, we exploit the temporal resolution of our comparative analysis to report the first marker genes for auxospore identity called AAE1‐3 ("Auxospore‐Associated Expression"). Altogether, we introduce a multi‐species model of the transcriptional dynamics during size restoration in diatoms and highlight conserved gene expression dynamics during different stages of sexual reproduction. [ABSTRACT FROM AUTHOR]

Published
2024
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5. The Seminavis robusta genome provides insights into the evolutionary adaptations of benthic diatoms

Author

Osuna-Cruz, Cristina Maria, Bilcke, Gust, Vancaester, Emmelien, De Decker, Sam, Bones, Atle M., Winge, Per, Poulsen, Nicole, Bulankova, Petra, Verhelst, Bram, Audoor, Sien, Belisova, Darja, Pargana, Aikaterini, Russo, Monia, Stock, Frederike, Cirri, Emilio, Brembu, Tore, Pohnert, Georg, Piganeau, Gwenael, Ferrante, Maria Immacolata, Mock, Thomas, Sterck, Lieven, Sabbe, Koen, De Veylder, Lieven, Vyverman, Wim, and Vandepoele, Klaas

Published
2020
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7. Genome of wild olive and the evolution of oil biosynthesis

Author

Unver, Turgay, Wu, Zhangyan, Sterck, Lieven, Turktas, Mine, Lohaus, Rolf, Li, Zhen, Yang, Ming, He, Lijuan, Deng, Tianquan, Escalante, Francisco Javier, Llorens, Carlos, Roig, Francisco J., Parmaksiz, Iskender, Dundar, Ekrem, Xie, Fuliang, Zhang, Baohong, Ipek, Arif, Uranbey, Serkan, Erayman, Mustafa, Ilhan, Emre, Badad, Oussama, Ghazal, Hassan, Lightfoot, David A., Kasarla, Pavan, Colantonio, Vincent, Tombuloglu, Huseyin, Hernandez, Pilar, Mete, Nurengin, Cetin, Oznur, Van Montagu, Marc, Yang, Huanming, Gao, Qiang, Dorado, Gabriel, and Van de Peer, Yves

Published
2017

8. Author Correction: The Seminavis robusta genome provides insights into the evolutionary adaptations of benthic diatoms

Author

Osuna-Cruz, Cristina Maria, Bilcke, Gust, Vancaester, Emmelien, De Decker, Sam, Bones, Atle M., Winge, Per, Poulsen, Nicole, Bulankova, Petra, Verhelst, Bram, Audoor, Sien, Belisova, Darja, Pargana, Aikaterini, Russo, Monia, Stock, Frederike, Cirri, Emilio, Brembu, Tore, Pohnert, Georg, Piganeau, Gwenael, Ferrante, Maria Immacolata, Mock, Thomas, Sterck, Lieven, Sabbe, Koen, De Veylder, Lieven, Vyverman, Wim, and Vandepoele, Klaas

Published
2020
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10. Maritime Pine Genomics in Focus

Author

Perdiguero, Pedro [0000-0002-5471-9550], Sterck, Lieven [0000-0001-7116-4000], Sterck, Lieven, María N., Cañas R.A., de Miguel, Marina, Perdiguero, Pedro, Perdiguero, Pedro [0000-0002-5471-9550], Sterck, Lieven [0000-0001-7116-4000], Sterck, Lieven, María N., Cañas R.A., de Miguel, Marina, and Perdiguero, Pedro

Abstract

The advent of next-generation genome sequencing technologies has allowed approaching the sequencing and analysis of large and complex conifer genomes. Maritime pine (Pinus pinaster Ait.) is an economically and ecologically important conifer species widely distributed in South-West Europe, which shows a significant genetic and adaptive variability. This chapter takes on the task of reviewing the insights into the maritime pine genome sequencing breakthrough and its impact on downstream analysis. Maritime pine genome sequencing and assembly approaches are described along with the impact of related tools. A section of the state-of-the-art research on comparative, functional, structural, and translational genomics aimed at dissecting the genetic basis and the specific regulation of biological processes underlying the expression of traits of interest in maritime pine and other conifers is also described. Perspectives about the impact of these tools as well as additional research approaches are discussed.

Published
2022

13. Genomics of Clinal Local Adaptation in Pinus sylvestris Under Continuous Environmental and Spatial Genetic Setting

Author

European Commission, Academy of Finland, Ghent University, Tyrmi, Jaakko S. [0000-0002-4757-6563], Vuosku, Jaana [0000-0001-9701-5759], Acosta, Juan José [0000-0002-9429-5166], Li, Zhen [0000-0001-8920-9270], Sterck, Lieven [0000-0001-7116-4000], Cervera, María Teresa [0000-0001-6797-2347], Savolainen, Outi [0000-0001-9851-7945], Pyhäjärvi, Tanja [0000-0001-6958-5172], Tyrmi, Jaakko S., Vuosku, Jaana, Acosta, Juan José, Li, Zhen, Sterck, Lieven, Cervera, María Teresa, Savolainen, Outi, Pyhäjärvi, Tanja, European Commission, Academy of Finland, Ghent University, Tyrmi, Jaakko S. [0000-0002-4757-6563], Vuosku, Jaana [0000-0001-9701-5759], Acosta, Juan José [0000-0002-9429-5166], Li, Zhen [0000-0001-8920-9270], Sterck, Lieven [0000-0001-7116-4000], Cervera, María Teresa [0000-0001-6797-2347], Savolainen, Outi [0000-0001-9851-7945], Pyhäjärvi, Tanja [0000-0001-6958-5172], Tyrmi, Jaakko S., Vuosku, Jaana, Acosta, Juan José, Li, Zhen, Sterck, Lieven, Cervera, María Teresa, Savolainen, Outi, and Pyhäjärvi, Tanja

Abstract

Understanding the consequences of local adaptation at the genomic diversity is a central goal in evolutionary genetics of natural populations. In species with large continuous geographical distributions the phenotypic signal of local adaptation is frequently clear, but the genetic basis often remains elusive. We examined the patterns of genetic diversity in Pinus sylvestris, a keystone species in many Eurasian ecosystems with a huge distribution range and decades of forestry research showing that it is locally adapted to the vast range of environmental conditions. Making P. sylvestris an even more attractive subject of local adaptation study, population structure has been shown to be weak previously and in this study. However, little is known about the molecular genetic basis of adaptation, as the massive size of gymnosperm genomes has prevented large scale genomic surveys. We generated a both geographically and genomically extensive dataset using a targeted sequencing approach. By applying divergence-based and landscape genomics methods we identified several loci contributing to local adaptation, but only few with large allele frequency changes across latitude. We also discovered a very large (ca. 300 Mbp) putative inversion potentially under selection, which to our knowledge is the first such discovery in conifers. Our results call for more detailed analysis of structural variation in relation to genomic basis of local adaptation, emphasize the lack of large effect loci contributing to local adaptation in the coding regions and thus point out the need for more attention toward multi-locus analysis of polygenic adaptation.

Published
2020

14. Molecular study of drought response in the Mediterranean conifer Pinus pinaster Ait.: Differential transcriptomic profiling reveals constitutive water deficit-independent drought tolerance mechanisms

Author

Ministerio de Economía, Industria y Competitividad (España), Agencia Estatal de Investigación (España), European Commission, Fundação para a Ciência e a Tecnologia (Portugal), de María, Nuria [0000-0003-4506-3980], Guevara, M Ángeles [0000-0001-7399-3136], Perdiguero, Pedro [0000-0002-5471-9550], Vélez, M. Dolores [0000-0001-8871-5737], Cabezas Martínez, José Antonio [0000-0002-4728-6072], López-Hinojosa, Miriam [0000-0002-7495-1517], Li, Zhen [0000-0001-8920-9270], Pizarro, Alberto [0000-0002-0346-3743], Sterck, Lieven [0000-0001-7116-4000], Sánchez-Gómez, D. [0000-0002-0588-9713], Miguel, Célia [0000-0002-1427-952X], Collada, Carmen [0000-0003-0236-1312], Díaz-Sala, Carmen [0000-0001-6249-7540], Cervera, María Teresa [0000-0001-6797-2347], de María, Nuria, Guevara, M Ángeles, Perdiguero, Pedro, Vélez, M. Dolores, Cabezas Martínez, José Antonio, López-Hinojosa, Miriam, Li, Zhen, Diáz, Luís Manuel, Pizarro, Alberto, Mancha, José Antonio, Sterck, Lieven, Sánchez-Gómez, D., Miguel, Célia, Collada, Carmen, Díaz-Sala, Carmen, Cervera, María Teresa, Ministerio de Economía, Industria y Competitividad (España), Agencia Estatal de Investigación (España), European Commission, Fundação para a Ciência e a Tecnologia (Portugal), de María, Nuria [0000-0003-4506-3980], Guevara, M Ángeles [0000-0001-7399-3136], Perdiguero, Pedro [0000-0002-5471-9550], Vélez, M. Dolores [0000-0001-8871-5737], Cabezas Martínez, José Antonio [0000-0002-4728-6072], López-Hinojosa, Miriam [0000-0002-7495-1517], Li, Zhen [0000-0001-8920-9270], Pizarro, Alberto [0000-0002-0346-3743], Sterck, Lieven [0000-0001-7116-4000], Sánchez-Gómez, D. [0000-0002-0588-9713], Miguel, Célia [0000-0002-1427-952X], Collada, Carmen [0000-0003-0236-1312], Díaz-Sala, Carmen [0000-0001-6249-7540], Cervera, María Teresa [0000-0001-6797-2347], de María, Nuria, Guevara, M Ángeles, Perdiguero, Pedro, Vélez, M. Dolores, Cabezas Martínez, José Antonio, López-Hinojosa, Miriam, Li, Zhen, Diáz, Luís Manuel, Pizarro, Alberto, Mancha, José Antonio, Sterck, Lieven, Sánchez-Gómez, D., Miguel, Célia, Collada, Carmen, Díaz-Sala, Carmen, and Cervera, María Teresa

Abstract

Adaptation of long-living forest trees to respond to environmental changes is essential to secure their performance under adverse conditions. Water deficit is one of the most significant stress factors determining tree growth and survival. Maritime pine (Pinus pinaster Ait.), the main source of softwood in southwestern Europe, is subjected to recurrent drought periods which, according to climate change predictions for the years to come, will progressively increase in the Mediterranean region. The mechanisms regulating pine adaptive responses to environment are still largely unknown. The aim of this work was to go a step further in understanding the molecular mechanisms underlying maritime pine response to water stress and drought tolerance at the whole plant level. A global transcriptomic profiling of roots, stems, and needles was conducted to analyze the performance of siblings showing contrasted responses to water deficit from an ad hoc designed full-sib family. Although P. pinaster is considered a recalcitrant species for vegetative propagation in adult phase, the analysis was conducted using vegetatively propagated trees exposed to two treatments: well-watered and moderate water stress. The comparative analyses led us to identify organ-specific genes, constitutively expressed as well as differentially expressed when comparing control versus water stress conditions, in drought-sensitive and drought-tolerant genotypes. Different response strategies can point out, with tolerant individuals being pre-adapted for coping with drought by constitutively expressing stress-related genes that are detected only in latter stages on sensitive individuals subjected to drought.

Published
2020

20. Legume Genome Evolution Viewed through the Medicago truncatula and Lotus japonicus Genomes

Author

Cannon, Steven B., Sterck, Lieven, Rombauts, Stephane, Sato, Shusei, Cheung, Foo, Gouzy, Jérôme, Wang, Xiaohong, Mudge, Joann, Vasdewani, Jayprakash, Scheix, Thomas, Spannagl, Manuel, Monaghan, Erin, Nicholson, Christine, Humphray, Sean J., Schoof, Heiko, Mayer, Klaus F. X., Rogers, Jane, Quétier, Francis, Oldroyd, Giles E., Debellé, Frédéric, Cook, Douglas R., Retzel, Ernest F., Roe, Bruce A., Town, Christopher D., Tabata, Satoshi, van de Peer, Yves, and Young, Nevin D.

Published
2006
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21. The genome of Eucalyptus grandis

Author

Myburg, Alexander A., Grattapaglia, Dario, Tuskan, Gerald A., Hellsten, Uffe, Hayes, Richard D., Grimwood, Jane, Jenkins, Jerry, Lindquist, Erika, Tice, Hope, Bauer, Diane, Goodstein, David M., Dubchak, Inna, Poliakov, Alexandre, Mizrachi, Eshchar, Kullan, Anand R. K., Hussey, Steven G., Pinard, Desre, van der Merwe, Karen, Singh, Pooja, van Jaarsveld, Ida, Silva-Junior, Orzenil B., Togawa, Roberto C., Pappas, Marilia R., Faria, Danielle A., Sansaloni, Carolina P., Petroli, Cesar D., Yang, Xiaohan, Ranjan, Priya, Tschaplinski, Timothy J., Ye, Chu-Yu, Li, Ting, Sterck, Lieven, Vanneste, Kevin, Murat, Florent, Soler, Marçal, Clemente, Hélène San, Saidi, Naijib, Cassan-Wang, Hua, Dunand, Christophe, Hefer, Charles A., Bornberg-Bauer, Erich, Kersting, Anna R., Vining, Kelly, Amarasinghe, Vindhya, Ranik, Martin, Naithani, Sushma, Elser, Justin, Boyd, Alexander E., Liston, Aaron, Spatafora, Joseph W., Dharmwardhana, Palitha, Raja, Rajani, Sullivan, Christopher, Romanel, Elisson, Alves-Ferreira, Marcio, Külheim, Carsten, Foley, William, Carocha, Victor, Paiva, Jorge, Kudrna, David, Brommonschenkel, Sergio H., Pasquali, Giancarlo, Byrne, Margaret, Rigault, Philippe, Tibbits, Josquin, Spokevicius, Antanas, Jones, Rebecca C., Steane, Dorothy A., Vaillancourt, René E., Potts, Brad M., Joubert, Fourie, Barry, Kerrie, Pappas, Georgios J., Strauss, Steven H., Jaiswal, Pankaj, Grima-Pettenati, Jacqueline, Salse, Jérôme, Van de Peer, Yves, Rokhsar, Daniel S., and Schmutz, Jeremy

Published
2014
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24. First draft genome assembly of the desert locust, Schistocerca gregaria - extended data

Author

Verlinden, Heleen, Sterck, Lieven, Li, Jia, Li, Zhen, Yssel, Anna, Gansemans, Yannick, Verdonck, Rik, Holtof, Michiel, Hojun Song, Matheson, Tom, Ott, Swidbert, Deforce, Dieter, Van Nieuwerburgh, Filip, Van De Peer, Yves, Broeck, Jozef Vanden, Behmer, Spencer, and Sword, Gregory

Subjects
animal structures
Abstract

Supplementary Methods: Animal material; Genomic DNA extraction; Library construction, sequencing for RNA-Seq and de novo transcriptome assembly Supplementary Table S1. Available Polyneopteran genomes (incl. Schistocerca gregaria for comparison) Supplementary Table S2. Software parameter settings Supplementary Table S3. Transfer RNA (tRNA), microRNA (miRNA), small nuclear RNA (snRNA) and ribosomal RNA (rRNA) content of the desert locust genome Supplementary Table S4. Desert locust genome annotation details Supplementary Table S5. BUSCO assessments for the genomes of the desert locust, Schistocerca gregaria, and the migratory locust, Locusta migratoria (Wang et al., 2014) Supplementary Table S6. Functional annotation of the proteome of the desert locust

Published
2021
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25. First draft genome assembly of the desert locust, Schistocerca gregaria

Author

Verlinden, Heleen, primary, Sterck, Lieven, additional, Li, Jia, additional, Li, Zhen, additional, Yssel, Anna, additional, Gansemans, Yannick, additional, Verdonck, Rik, additional, Holtof, Michiel, additional, Song, Hojun, additional, Behmer, Spencer T., additional, Sword, Gregory A., additional, Matheson, Tom, additional, Ott, Swidbert R., additional, Deforce, Dieter, additional, Van Nieuwerburgh, Filip, additional, Van de Peer, Yves, additional, and Vanden Broeck, Jozef, additional

Published
2021
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28. Additional file 1 of instaGRAAL: chromosome-level quality scaffolding of genomes using a proximity ligation-based scaffolder

Author

Lyam Baudry, Guiglielmoni, Nadège, Marie-Nelly, Hervé, Cormier, Alexandre, Marbouty, Martial, Komlan Avia, Mie, Yann Loe, Godfroy, Olivier, Sterck, Lieven, J. Mark Cock, Zimmer, Christophe, Coelho, Susana M., and Koszul, Romain

Subjects
ComputingMethodologies_DOCUMENTANDTEXTPROCESSING, ComputingMilieux_COMPUTERSANDEDUCATION, Data_FILES, ComputerApplications_COMPUTERSINOTHERSYSTEMS
Abstract

Additional file 1. Supplementary tables and figures.

Published
2020
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29. Molecular study of drought response in the Mediterranean conifer Pinus pinaster Ait.: Differential transcriptomic profiling reveals constitutive water deficit‐independent drought tolerance mechanisms

Author

María, Nuria de, Guevara, María Ángeles, Pedro Perdiguero, Vélez, María Dolores, Cabezas, José Antonio, López‐Hinojosa, Miriam, Li, Zhen, Díaz, Luís Manuel, Pizarro, Alberto, Mancha, José Antonio, Sterck, Lieven, Sánchez‐Gómez, David, Miguel, Célia, Cervera, María Teresa, Collada, Carmen, Díaz‐Sala, María Carmen, Perdiguero Jiménez, Pedro, María, Nuria de, Guevara, María Ángeles, Pedro Perdiguero, Vélez, María Dolores, Cabezas, José Antonio, López‐Hinojosa, Miriam, Li, Zhen, Díaz, Luís Manuel, Pizarro, Alberto, Mancha, José Antonio, Sterck, Lieven, Sánchez‐Gómez, David, Miguel, Célia, Cervera, María Teresa, Collada, Carmen, Díaz‐Sala, María Carmen, and Perdiguero Jiménez, Pedro

Abstract

ACKNOWLEDGMENTS I. Aranda (INIA-CIFOR) is gratefully acknowledged for his valuable collaboration and support in obtaining and interpreting data on physiology. D. Sobral (Instituto Gulbenkian de Ciência, Portugal) is gratefully acknowledged for his advice in the bioinformatics analyses. Bartolomé Sabater is gratefully acknowledged for critical review of the manuscript. S. Ferrándiz (INIA-CIFOR) is gratefully acknowledged for helping with the preparation of the manuscript. This work was supported by the Spanish Ministry of Economy, Industry and Competitiveness (AGL2015-66048-C2-1-R; RTI2018-098015-B-I00; IMP2018-005)]; European Union's Seventh Framework Programme 2007-2013 (FP7-289841); EU H2020 Programme (H2020-676559); Fundação para a Ciência e a Tecnologia, FCT (IF/01168/2013; UID/Multi/04551/2013); and People Programme, Marie Curie Actions (PIEF-GA-2013-627761)., Adaptation of long-living forest trees to respond to environmental changes is essential to secure their performance under adverse conditions. Water deficit is one of the most significant stress factors determining tree growth and survival. Maritime pine (Pinus pinaster Ait.), the main source of softwood in southwestern Europe, is subjected to recurrent drought periods which, according to climate change predictions for the years to come, will progressively increase in the Mediterranean region. The mechanisms regulating pine adaptive responses to environment are still largely unknown. The aim of this work was to go a step further in understanding the molecular mechanisms underlying maritime pine response to water stress and drought tolerance at the whole plant level. A global transcriptomic profiling of roots, stems, and needles was conducted to analyze the performance of siblings showing contrasted responses to water deficit from an ad hoc designed full-sib family. Although P. pinaster is considered a recalcitrant species for vegetative propagation in adult phase, the analysis was conducted using vegetatively propagated trees exposed to two treatments: well-watered and moderate water stress. The comparative analyses led us to identify organ-specific genes, constitutively expressed as well as differentially expressed when comparing control versus water stress conditions, in drought-sensitive and drought-tolerant genotypes. Different response strategies can point out, with tolerant individuals being pre-adapted for coping with drought by constitutively expressing stress-related genes that are detected only in latter stages on sensitive individuals subjected to drought, Depto. de Genética, Fisiología y Microbiología, Fac. de Ciencias Biológicas, TRUE, pub

Published
2020

31. The Ectocarpus Genome and Brown Algal Genomics

Author

Cock, J. Mark, primary, Sterck, Lieven, additional, Ahmed, Sophia, additional, Allen, Andrew E., additional, Amoutzias, Grigoris, additional, Anthouard, Veronique, additional, Artiguenave, François, additional, Arun, Alok, additional, Aury, Jean-Marc, additional, Badger, Jonathan H., additional, Beszteri, Bank, additional, Billiau, Kenny, additional, Bonnet, Eric, additional, Bothwell, John H., additional, Bowler, Chris, additional, Boyen, Catherine, additional, Brownlee, Colin, additional, Carrano, Carl J., additional, Charrier, Bénédicte, additional, Cho, Ga Youn, additional, Coelho, Susana M., additional, Collén, Jonas, additional, Le Corguillé, Gildas, additional, Corre, Erwan, additional, Dartevelle, Laurence, additional, Da Silva, Corinne, additional, Delage, Ludovic, additional, Delaroque, Nicolas, additional, Dittami, Simon M., additional, Doulbeau, Sylvie, additional, Elias, Marek, additional, Farnham, Garry, additional, Gachon, Claire M.M., additional, Godfroy, Olivier, additional, Gschloessl, Bernhard, additional, Heesch, Svenja, additional, Jabbari, Kamel, additional, Jubin, Claire, additional, Kawai, Hiroshi, additional, Kimura, Kei, additional, Kloareg, Bernard, additional, Küpper, Frithjof C., additional, Lang, Daniel, additional, Le Bail, Aude, additional, Luthringer, Rémy, additional, Leblanc, Catherine, additional, Lerouge, Patrice, additional, Lohr, Martin, additional, Lopez, Pascal J., additional, Macaisne, Nicolas, additional, Martens, Cindy, additional, Maumus, Florian, additional, Michel, Gurvan, additional, Miranda-Saavedra, Diego, additional, Morales, Julia, additional, Moreau, Hervé, additional, Motomura, Taizo, additional, Nagasato, Chikako, additional, Napoli, Carolyn A., additional, Nelson, David R., additional, Nyvall-Collén, Pi, additional, Peters, Akira F., additional, Pommier, Cyril, additional, Potin, Philippe, additional, Poulain, Julie, additional, Quesneville, Hadi, additional, Read, Betsy, additional, Rensing, Stefan A., additional, Ritter, Andrés, additional, Rousvoal, Sylvie, additional, Samanta, Manoj, additional, Samson, Gaelle, additional, Schroeder, Declan C., additional, Scornet, Delphine, additional, Ségurens, Béatrice, additional, Strittmatter, Martina, additional, Tonon, Thierry, additional, Tregear, James W., additional, Valentin, Klaus, additional, Von Dassow, Peter, additional, Yamagishi, Takahiro, additional, Rouzé, Pierre, additional, Van de Peer, Yves, additional, and Wincker, Patrick, additional

Published
2012
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33. The Medicago genome provides insight into the evolution of rhizobial symbioses

Author

Young, Nevin D., Debellé, Frédéric, Oldroyd, Giles E. D., Geurts, Rene, Cannon, Steven B., Udvardi, Michael K., Benedito, Vagner A., Mayer, Klaus F. X., Gouzy, Jérôme, Schoof, Heiko, Van de Peer, Yves, Proost, Sebastian, Cook, Douglas R., Meyers, Blake C., Spannagl, Manuel, Cheung, Foo, De Mita, Stéphane, Krishnakumar, Vivek, Gundlach, Heidrun, Zhou, Shiguo, Mudge, Joann, Bharti, Arvind K., Murray, Jeremy D., Naoumkina, Marina A., Rosen, Benjamin, Silverstein, Kevin A. T., Tang, Haibao, Rombauts, Stephane, Zhao, Patrick X., Zhou, Peng, Barbe, Valérie, Bardou, Philippe, Bechner, Michael, Bellec, Arnaud, Berger, Anne, Bergès, Hélène, Bidwell, Shelby, Bisseling, Ton, Choisne, Nathalie, Couloux, Arnaud, Denny, Roxanne, Deshpande, Shweta, Dai, Xinbin, Doyle, Jeff J., Dudez, Anne-Marie, Farmer, Andrew D., Fouteau, Stéphanie, Franken, Carolien, Gibelin, Chrystel, Gish, John, Goldstein, Steven, González, Alvaro J., Green, Pamela J., Hallab, Asis, Hartog, Marijke, Hua, Axin, Humphray, Sean J., Jeong, Dong-Hoon, Jing, Yi, Jöcker, Anika, Kenton, Steve M., Kim, Dong-Jin, Klee, Kathrin, Lai, Hongshing, Lang, Chunting, Lin, Shaoping, Macmil, Simone L., Magdelenat, Ghislaine, Matthews, Lucy, McCorrison, Jamison, Monaghan, Erin L., Mun, Jeong-Hwan, Najar, Fares Z., Nicholson, Christine, Noirot, Céline, O’Bleness, Majesta, Paule, Charles R., Poulain, Julie, Prion, Florent, Qin, Baifang, Qu, Chunmei, Retzel, Ernest F., Riddle, Claire, Sallet, Erika, Samain, Sylvie, Samson, Nicolas, Sanders, Iryna, Saurat, Olivier, Scarpelli, Claude, Schiex, Thomas, Segurens, Béatrice, Severin, Andrew J., Sherrier, Janine D., Shi, Ruihua, Sims, Sarah, Singer, Susan R., Sinharoy, Senjuti, Sterck, Lieven, Viollet, Agnès, Wang, Bing-Bing, Wang, Keqin, Wang, Mingyi, Wang, Xiaohong, Warfsmann, Jens, Weissenbach, Jean, White, Doug D., White, Jim D., Wiley, Graham B., Wincker, Patrick, Xing, Yanbo, Yang, Limei, Yao, Ziyun, Ying, Fu, Zhai, Jixian, Zhou, Liping, Zuber, Antoine, Dénarié, Jean, Dixon, Richard A., May, Gregory D., Schwartz, David C., Rogers, Jane, Quétier, Francis, Town, Christopher D., and Roe, Bruce A.

Published
2011
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34. Molecular study of drought response in the Mediterranean conifer Pinus pinaster Ait.: Differential transcriptomic profiling reveals constitutive water deficit‐independent drought tolerance mechanisms

Author

de María, Nuria, primary, Guevara, María Ángeles, additional, Perdiguero, Pedro, additional, Vélez, María Dolores, additional, Cabezas, José Antonio, additional, López‐Hinojosa, Miriam, additional, Li, Zhen, additional, Díaz, Luís Manuel, additional, Pizarro, Alberto, additional, Mancha, José Antonio, additional, Sterck, Lieven, additional, Sánchez‐Gómez, David, additional, Miguel, Célia, additional, Collada, Carmen, additional, Díaz‐Sala, María Carmen, additional, and Cervera, María Teresa, additional

Published
2020
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36. First draft genome assembly of the desert locust, Schistocerca gregaria

Author

Verlinden, Heleen, primary, Sterck, Lieven, additional, Li, Jia, additional, Li, Zhen, additional, Yssel, Anna, additional, Gansemans, Yannick, additional, Verdonck, Rik, additional, Holtof, Michiel, additional, Song, Hojun, additional, Behmer, Spencer T., additional, Sword, Gregory A., additional, Matheson, Tom, additional, Ott, Swidbert R., additional, Deforce, Dieter, additional, Van Nieuwerburgh, Filip, additional, Van de Peer, Yves, additional, and Vanden Broeck, Jozef, additional

Published
2020
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39. TheSeminavis robustagenome provides insights into the evolutionary adaptations of benthic diatoms

Author

Osuna-Cruz, Cristina Maria, primary, Bilcke, Gust, additional, Vancaester, Emmelien, additional, De Decker, Sam, additional, Poulsen, Nicole, additional, Bulankova, Petra, additional, Verhelst, Bram, additional, Audoor, Sien, additional, Stojanovova, Darja, additional, Pargana, Aikaterini, additional, Russo, Monia, additional, Stock, Frederike, additional, Cirri, Emilio, additional, Brembu, Tore, additional, Pohnert, Georg, additional, Winge, Per, additional, Bones, Atle M., additional, Piganeu, Gwenael, additional, Ferrante, Maria Immacolata, additional, Mock, Thomas, additional, Sterck, Lieven, additional, Sabbe, Koen, additional, De Veylder, Lieven, additional, Vyverman, Wim, additional, and Vandepoele, Klaas, additional

Published
2020
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40. Chromosome-level quality scaffolding of brown algal genomes using InstaGRAAL, a proximity ligation-based scaffolder

Author

Baudry, Lyam, primary, Marbouty, Martial, additional, Marie-Nelly, Hervé, additional, Cormier, Alexandre, additional, Guiglielmoni, Nadège, additional, Avia, Komlan, additional, Mie, Yann Loe, additional, Godfroy, Olivier, additional, Sterck, Lieven, additional, Cock, J. Mark, additional, Zimmer, Christophe, additional, Coelho, Susana M., additional, and Koszul, Romain, additional

Published
2019
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41. The Ectocarpus genome and the independent evolution of multicellularity in brown algae

Author

Cock, Mark J., Sterck, Lieven, Rouzé, Pierre, Scornet, Delphine, Allen, Andrew E., Amoutzias, Grigoris, Anthouard, Veronique, Artiguenave, François, Aury, Jean-Marc, Badger, Jonathan H., Beszteri, Bank, Billiau, Kenny, Bonnet, Eric, Bothwell, John H., Bowler, Chris, Boyen, Catherine, Brownlee, Colin, Carrano, Carl J., Charrier, Bénédicte, Cho, Ga Youn, Coelho, Susana M., Collén, Jonas, Corre, Erwan, Da Silva, Corinne, Delage, Ludovic, Delaroque, Nicolas, Dittami, Simon M., Doulbeau, Sylvie, Elias, Marek, Farnham, Garry, Gachon, Claire M. M., Gschloessl, Bernhard, Heesch, Svenja, Jabbari, Kamel, Jubin, Claire, Kawai, Hiroshi, Kimura, Kei, Kloareg, Bernard, Küpper, Frithjof C., Lang, Daniel, Le Bail, Aude, Leblanc, Catherine, Lerouge, Patrice, Lohr, Martin, Lopez, Pascal J., Martens, Cindy, Maumus, Florian, Michel, Gurvan, Miranda-Saavedra, Diego, Morales, Julia, Moreau, Hervé, Motomura, Taizo, Nagasato, Chikako, Napoli, Carolyn A., Nelson, David R., Nyvall-Collén, Pi, Peters, Akira F., Pommier, Cyril, Potin, Philippe, Poulain, Julie, Quesneville, Hadi, Read, Betsy, Rensing, Stefan A., Ritter, Andrés, Rousvoal, Sylvie, Samanta, Manoj, Samson, Gaelle, Schroeder, Declan C., Ségurens, Béatrice, Strittmatter, Martina, Tonon, Thierry, Tregear, James W., Valentin, Klaus, von Dassow, Peter, Yamagishi, Takahiro, Van de Peer, Yves, and Wincker, Patrick

Published
2010
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42. Single-copy genes as molecular markers for phylogenomic studies in seed plants

Author

Li, Zhen [0000-0001-8920-9270], Sterck, Lieven [0000-0001-7116-4000], Cervera, María Teresa [0000-0001-6797-2347], Li, Zhen, Torre Reoyo, Ana de la, Sterck, Lieven, Cánovas, F. M., Avila, C., Merino Pérez, Irene, Cabezas Martínez, José Antonio, Cervera, María Teresa, Ingvarsson, P. K., Van de Peer, Y., Li, Zhen [0000-0001-8920-9270], Sterck, Lieven [0000-0001-7116-4000], Cervera, María Teresa [0000-0001-6797-2347], Li, Zhen, Torre Reoyo, Ana de la, Sterck, Lieven, Cánovas, F. M., Avila, C., Merino Pérez, Irene, Cabezas Martínez, José Antonio, Cervera, María Teresa, Ingvarsson, P. K., and Van de Peer, Y.

Abstract

Phylogenetic relationships among seed plant taxa, especially within the gymnosperms, remain contested. In contrast to angiosperms, for which several genomic, transcriptomic and phylogenetic resources are available, there are few, if any,molecularmarkers that allow broad comparisons among gymnosperm species. With few gymnosperm genomes available, recently obtained transcriptomes in gymnosperms are a great addition to identifying single-copy gene families as molecular markers for phylogenomic analysis in seed plants. Taking advantage of an increasing number of available genomes and transcriptomes, we identified singlecopy genes in a broad collection of seed plants and used these to infer phylogenetic relationships between major seed plant taxa. This study aims at extending the current phylogenetic toolkit for seed plants, assessing its ability for resolving seed plant phylogeny, and discussing potential factors affecting phylogenetic reconstruction. In total, we identified 3,072 single-copy genes in 31 gymnosperms and 2,156 single-copy genes in 34 angiosperms. All studied seed plants shared 1,469 single-copy genes, which are generally involved in functions likeDNAmetabolism, cell cycle, and photosynthesis.Aselected set of 106 single-copy genes provided good resolution for the seed plant phylogeny except for gnetophytes. Although some of our analyses support a sister relationship between gnetophytes and other gymnosperms, phylogenetic trees from concatenated alignments without 3rd codon positions and amino acid alignments under theCAT+GTRmodel, support gnetophytes as a sister group to Pinaceae.Our phylogenomic analyses demonstrate that, in general, single-copy genes can uncover both recent and deep divergences of seed plant phylogeny. © The Author 2017. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution.

Published
2017

47. Ten steps to get started in Genome Assembly and Annotation.

Author

Dominguez Del Angel, Victoria, Hjerde, Erik, Sterck, Lieven, Capella-Gutierrez, Salvadors, Notredame, Cederic, Vinnere, Olga, Amselem, Joelle, Bouri, Laurent, Bocs, Stephanie, Klopp, Christophe, Gibrat, Jean-Francois, Vlasova, Anna, Leskosek, Brane L, Soler, Lucile, Binzer-Panchal, Mahesh, Lantz, Henrik, Dominguez Del Angel, Victoria, Hjerde, Erik, Sterck, Lieven, Capella-Gutierrez, Salvadors, Notredame, Cederic, Vinnere, Olga, Amselem, Joelle, Bouri, Laurent, Bocs, Stephanie, Klopp, Christophe, Gibrat, Jean-Francois, Vlasova, Anna, Leskosek, Brane L, Soler, Lucile, Binzer-Panchal, Mahesh, and Lantz, Henrik

Abstract

As a part of the ELIXIR-EXCELERATE efforts in capacity building, we present here 10 steps to facilitate researchers getting started in genome assembly and genome annotation. The guidelines given are broadly applicable, intended to be stable over time, and cover all aspects from start to finish of a general assembly and annotation project. Intrinsic properties of genomes are discussed, as is the importance of using high quality DNA. Different sequencing technologies and generally applicable workflows for genome assembly are also detailed. We cover structural and functional annotation and encourage readers to also annotate transposable elements, something that is often omitted from annotation workflows. The importance of data management is stressed, and we give advice on where to submit data and how to make your results Findable, Accessible, Interoperable, and Reusable (FAIR).

Published
2018
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48. Ten steps to get started in Genome Assembly and Annotation

Author

Barcelona Supercomputing Center, Dominguez del Angel, Victoria, Hjerde, Erik, Sterck, Lieven, Capella-Gutierrez, Salvador, Notredame, Cederic, Vinnere Pettersson, Olga, Amselem, Joelle, Bouri, Laurent, Bocs, Stephanie, Klopp, Christophe, Gibrat, Jean-Francois, Vlasova, Anna, Leskosek, Brane L., Soler, Lucile, Binzer-Panchal, Mahesh, Lantz, Henrik, Barcelona Supercomputing Center, Dominguez del Angel, Victoria, Hjerde, Erik, Sterck, Lieven, Capella-Gutierrez, Salvador, Notredame, Cederic, Vinnere Pettersson, Olga, Amselem, Joelle, Bouri, Laurent, Bocs, Stephanie, Klopp, Christophe, Gibrat, Jean-Francois, Vlasova, Anna, Leskosek, Brane L., Soler, Lucile, Binzer-Panchal, Mahesh, and Lantz, Henrik

Abstract

As a part of the ELIXIR-EXCELERATE efforts in capacity building, we present here 10 steps to facilitate researchers getting started in genome assembly and genome annotation. The guidelines given are broadly applicable, intended to be stable over time, and cover all aspects from start to finish of a general assembly and annotation project. Intrinsic properties of genomes are discussed, as is the importance of using high quality DNA. Different sequencing technologies and generally applicable workflows for genome assembly are also detailed. We cover structural and functional annotation and encourage readers to also annotate transposable elements, something that is often omitted from annotation workflows. The importance of data management is stressed, and we give advice on where to submit data and how to make your results Findable, Accessible, Interoperable, and Reusable (FAIR)., ELIXIR-EXCELERATE is funded by the European Commission within the Research Infrastructures Programme of Horizon 2020 [676559]., Peer Reviewed, Postprint (published version)

Published
2018

49. Molecular study of drought response in the mediterranean conifer Pinus pinaster Ait.: protein-coding-transcript profiling

Author

María, Nuria de, Perdiguero, Pedro, Guevara, Mª Ángeles, Cabezas, José Antonio, Chaves, Inés, Li, Zhen, Costa, Bruno, Vélez, Mª Dolores, Rodrigues, Andreia, Pizarro, Alberto, Díaz, Luis Manuel, Mancha, José Antonio, Collada, Carmen, Sánchez-Gómez, David, Aranda, Ismael, Sterck, Lieven, Díaz-Sala, Carmen, Miguel, Celia M., and Cervera, M. Teresa

Subjects
Biología, Botánica
Abstract

The aim ofthis work is to go a step further towards the understanding ofthe molecular mechanisms underlying maritime pine response to water stress and drought tolerance.

Published
2017

50. Insights into the Evolution of Multicellularity from the Sea Lettuce Genome

Author

De Clerck, Olivier, primary, Kao, Shu-Min, additional, Bogaert, Kenny A., additional, Blomme, Jonas, additional, Foflonker, Fatima, additional, Kwantes, Michiel, additional, Vancaester, Emmelien, additional, Vanderstraeten, Lisa, additional, Aydogdu, Eylem, additional, Boesger, Jens, additional, Califano, Gianmaria, additional, Charrier, Benedicte, additional, Clewes, Rachel, additional, Del Cortona, Andrea, additional, D’Hondt, Sofie, additional, Fernandez-Pozo, Noe, additional, Gachon, Claire M., additional, Hanikenne, Marc, additional, Lattermann, Linda, additional, Leliaert, Frederik, additional, Liu, Xiaojie, additional, Maggs, Christine A., additional, Popper, Zoë A., additional, Raven, John A., additional, Van Bel, Michiel, additional, Wilhelmsson, Per K.I., additional, Bhattacharya, Debashish, additional, Coates, Juliet C., additional, Rensing, Stefan A., additional, Van Der Straeten, Dominique, additional, Vardi, Assaf, additional, Sterck, Lieven, additional, Vandepoele, Klaas, additional, Van de Peer, Yves, additional, Wichard, Thomas, additional, and Bothwell, John H., additional

Published
2018
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