Notre site utilise des cookies nécessaires à son bon fonctionnement. Pour améliorer votre expérience, d’autres cookies peuvent être utilisés : vous pouvez choisir de les désactiver. Cela reste modifiable à tout moment via le lien Cookies en bas de page.


Publications XYLOBIOTECH
Plomion et al. (2016) - Article de synthèse - Génomique des arbres forestiers


« Forest tree genomics: 10 achievements from the past 10 years and future prospects ». Annals of Forest Science, 73: 77-103, doi:10.1007/s13595-015-0488-3.

En lien également avec le plateau XYLOMIC

Plomion C, Bastien C, Bogeat-Triboulot M-B, Bouffier L, Déjardin A, Duplessis S, Fady B, Heuertz M, Le Gac A-L, Le Provost G, Legué V, Lelu-Walter M-A, Leplé J-C, Maury S, Morel A, Oddou-Muratorio S, Pilate G, Sanchez L, Scotti I, Scotti-Saintagne C, Segura V, Trontin J-F, Vacher C.

Collaboration FCBA et INRA d'Orléans pour la partie "Conifer embryo development" de cette revue


Key message: This review highlights some of the discoveries and applications made possible by “omics” technologies over the last 10 years and provides perspectives for pioneering research to increase our understanding of tree biology.

Context: A decade after the first forest tree genome sequence was released into the public domain, the rapidly evolving genomics and bioinformatics toolbox has advanced our understanding of the structure, functioning, and evolution of forest tree genomes.

Aims and methods: This review highlights some of the discoveries and applications that “omics” technologies have made possible for forest trees over the past 10 years.

Results: In this review, we start by our current understanding of genome evolution and intricacies of gene regulation for reproduction, development, and responses to biotic and abiotic stresses. We then skim over advances in interactome analysis and epigenomics, the knowledge of the extent of genetic variation within and between species, revealing micro- and
macro-evolutionary processes and species history, together with the complex architecture of quantitative traits. We finally end with applications in genetic resource conservation and breeding.

Conclusion: The knowledge gained through the use of these technologies has a huge potential impact for adapting forests to the main challenges they will have to face: changing demand from ecosystem services with potentially conflicting strategies in terms of conservation and use, as well as climate changes and associated threats. Genomics will undoubtedly play a major role over the next decade and beyond, not only to further understand the mechanisms underlying adaptation and evolution but also to develop and implement innovative management and policy actions to preserve the adaptability of natural forests and intensively managed plantations.

Modifié le vendredi 18 mars 2016