A genomic approach to the evolution, diversification and domestication of the genus citrus

• Autores: Carles Borredá Fernández
• Directores de la Tesis: Manuel Talón Cubillo (dir. tes.), Javier Terol Alcayde (dir. tes.), María Belén Pico Sirvent (tut. tes.)
• Lectura: En la Universitat Politècnica de València ( España ) en 2021
• Idioma: español
• Tribunal Calificador de la Tesis: Pere Arús Gorina (presid.), Bruno Contreras Moreira (secret.), Tokuro Shimizu (voc.)
• Programa de doctorado: Programa de Doctorado en Biotecnología por la Universitat Politècnica de València
• Materias:
  • Ciencias de la vida
    • Genética
    • Biología vegetal (botánica)
• Enlaces
  • Tesis en acceso abierto en: RiuNet
• Resumen

  • Citrus is a diverse genus within the Aurantioideae subfamily that comprises an undetermined number of pure species natively found in a vast territory extending from India to Japan and Australia. Besides pure species, countless citrus admixtures of commercial interest such as mandarins, oranges and lemons have been traditionally included in this genus, even though they are the product of several interspecific crosses between pure species. Recently, a genome-wide analysis provided the backbone of the Citrus phylogeny, showing that the wild species diverged from an ancestral citrus in a rapid radiation during the Late Miocene. Understanding the processes that shaped the evolution and domestication of the genus will provide novel insights in the field of plant genome evolution.

    In this doctoral thesis, multiple genomic approaches have been used to expand the existing knowledge on major determinants driving the processes of evolution, diversification and domestication in Citrus. First, a genome-wide Aurantioideae phylogeny was generated, revealing the existence of several independent dispersal events in this subfamily in the last 10 million years, from Asia to Africa and Australia, and rooting the Citrus genus within this subfamily. The Citrus phylogeny was then studied under the multispecies coalescent model, which can capture the variability generated during fast radiations. The dating of the speciation events allowed to advance original proposals on the paleogeographic events triggering the migration of the Citrus species through the South East Asian region.

    The Citrus radiation generated the great genetic and phenotypic diversity found in this genus. To investigate the effects of the Late Miocene climate change on the genomic structure of the Citrus pure species, the activity and evolution of retrotransposons, which can significantly alter the genome of their hosts, was analyzed. Most of the Citrus retrotransposon families are shared with Severinia buxifolia, an Aurantioideae species that diverged from Citrus more than 10 million years ago, implying that few retrotransposon families are specific to the genus Citrus. However, estimations of the retrotransposon insertion rates within Citrus revealed that, shortly after the radiation, the transposon activity rapidly changed among the different species. Hence, the data indicates that retrotransposon dynamics are linked to the stress caused by the Late Miocene climate change and the Citrus speciation, although specific responses likely depend on the particular evolutionary history of each species.

    The differences of gene expression in fruits of domesticated and wild cultivars were then studied to understand the role of interspecific hybridizations during Citrus domestication. The results presented suggest that these events, together with asexual propagation, were key for the domestication process. Different mechanisms explaining commercially relevant Citrus traits are also proposed. For example, pulp acidity in citrons and lemons is linked to an increased proton influx to the pulp vacuoles. The data also indicate that the peel pigmentation might be controlled by the additive effect of several minor genes, and not by a single gene or mechanism. Finally, an allele-dependent expression pattern of a chalcone synthase, involved in the flavonoid biosynthesis, advocates for the existence of a stepwise evolution in the mandarin flavonoid accumulation. All in all, the transcriptomic approach used in this work allowed to generate broader hypotheses that stand from a genus-wide perspective.

    Overall, the results provide a comprehensive framework of Citrus phylogenetic relationships, the effect of the mobile elements during its diversification and the role of interspecific hybridizations in the citrus domestication. The insights here exposed reveal the inherent complexity of the evolutionary history of this fascinating genus.